Tag Archives: Infectious diseases

Microbiology

Candida auris infection without epidemiologic links to a prior outbreak

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Dr. Priyom Bose, Ph.D.By Dr. Priyom Bose, Ph.D.Mar 23 2023Reviewed by Danielle Ellis, B.Sc.

The Centers for Disease Control and Prevention (CDC) has classified Candida auris (C. auris) as an urgent public threat due to its role in elevating mortality, its ability to persist in hospital environments, and the high possibility of developing pan-drug resistance.

Notably, a recent study published in the journal Open Forum Infectious Diseases has pointed out that surfaces near patients with C. auris quickly become re-contaminated after cleaning.

Existing research has not adequately elucidated the environmental reservoirs of C. auris. Further, few studies have reported epidemiologic links associated with C. auris infection. 

Study: The Emergence and Persistence of Candida auris in Western New York with no Epidemiologic Links: A Failure of Stewardship?. Image Credit: Kateryna Kon / ShutterstockStudy: The Emergence and Persistence of Candida auris in Western New York with no Epidemiologic Links: A Failure of Stewardship? Image Credit: Kateryna Kon / Shutterstock

Background

C. auris is a species of fungus that grows as yeast. It is one of the few species of the genus Candida which cause candidiasis in humans. In the past, C. auris infection was primarily found in cancer patients or those subjected to feeding tubes.

In the United States (US), the emergence of C. auris was traced to New York, and surveillance for this fungal infection was focused mainly on New York City to detect outbreaks. Recently, scientists investigated the association between genomic epidemiology and C. auris infection in Western New York.

A Case Study

The study describes the emergence of C. auris in a patient hospitalized at a small community hospital in Genesee County, New York (NY). In January 2022, C. auris was isolated from the urine culture of a 68-year-old male on the 51st day of hospitalization.

This patient had no known epidemiological connections outside his immediate community. Before his hospitalization, he was not exposed to other patients or family members associated with C. auris infection.

This patient had no history of organ transplantation, decubitus ulcers, hemodialysis, feeding tubes, or nursing home stays. He had an active lifestyle with a history of mild vascular dementia. He was hospitalized due to pneumonia and was prescribed azithromycin treatment.

Post hospitalization, he tested positive for severe acute respiratory syndrome coronavirus-2 (SARS-CoV-2) and was treated with dexamethasone (6 mg) daily for 10 days and remdesivir (200 mg) once, followed by 100 mg daily for five days.

Since the patient’s chest radiograph showed left lobar consolidation, he was further treated with empiric ceftriaxone and azithromycin. As the respiratory symptoms deteriorated, he received non-invasive positive pressure ventilation, with subsequent endotracheal intubation for eight days. He was successfully extubated. He developed a fever and received antimicrobial therapy for 73 days. The patient had a urinary catheter and a peripherally inserted central line in his arm for 35 days. 

Microbiology culture test and serum procalcitonin levels remained negative and within normal levels. On the 22nd day of hospitalization, Candida albicans were isolated from respiratory samples. On the 51st day, the urine culture revealed the presence of azole-resistant C. auris.

The isolated C. auris (MRSN101498) was forwarded to the Multidrug-resistant organism Repository and Surveillance Network (MRSN), where genomic sequencing was performed. After the patient was discharged, the hospital room was cleaned using hydrogen peroxide and peracetic acid, followed by ultraviolet-C light. Other patients who shared rooms with the patient with C. auris were tested for infection.

Study Outcomes

C. auris was not detected in the Western NY community hospital in the past year. Physicians stated that the patient received excessive antibiotic treatment for a prolonged period. Genomic studies revealed that the MRSN101498 genome sequence was closely related to the 2013 Indian strain with minor genomic differences. Interestingly, the K143R mutation in ERG11 was found in MRSN101498, which is associated with triazole resistance in Candida albicans.

Whole genome single nucleotide polymorphism (SNP) analysis also highlighted that MRSN101498 was strongly genetically related to four other isolates, with marginal differences.

These isolates were linked to an outbreak in March 2017 in a hospital 47 miles northeast of Rochester, NY. Based on the current findings, it is highly likely that isolates from Western NY share a recent common ancestor.

Study Importance

This case study is important for several reasons, including the absence of epidemiologic links to C.auris infection. Since reports from rural sectors are rare, this study addresses a vital surveillance ‘blind spot.’ 

However, the current study failed to identify the potential reservoirs of MRSN101498 in Western NY. Sporicidal disinfectants were inefficient for both Clostridioides difficile and C. auris. However, terminal cleaning protocols that included UV irradiation and sporicidal cleaning agents were able to eradicate C. auris effectively.

The current study highlights the role of excessive antibiotic exposure in the emergence of C. auris. It also indicates the challenges in eliminating fungi from hospital settings. The authors recommend proper antibiotic treatment and cleaning procedures for drug-resistant pathogens.

Journal reference:
Microbiology

Novel subset of memory B cells predicts long-lived antibody responses to influenza vaccination

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Reviewed by Emily Henderson, B.Sc.Mar 22 2023

Memory B cells play a critical role to provide long-term immunity after a vaccination or infection. In a study published in the journal Immunity, researchers describe a distinct and novel subset of memory B cells that predict long-lived antibody responses to influenza vaccination in humans.

These effector memory B cells appear to be poised for a rapid serum antibody response upon secondary challenge one year later, Anoma Nellore, M.D., Fran Lund, Ph.D., and colleagues at the University of Alabama at Birmingham and Emory University report. Evidence from transcriptional and epigenetic profiling shows that the cells in this subset differ from all previously described memory B cell subsets.

The UAB researchers identified the novel subset by the presence of FcRL5 receptor protein on the cell surface. In immunology, a profusion of different cell-surface markers is used to identify and separate immune-cell types. In the novel memory B cell subset, FcRL5 acts as a surrogate marker for positive expression of the T-bet transcription factor inside the cells. Various transcription factors act as master regulators to orchestrate the expression of many different gene sets as various cell types grow and differentiate.

Nellore, Lund and colleagues found that the FcRL5+ T-bet+ memory B cells can be detected seven days after immunization, and the presence of these cells correlates with vaccine antibody responses months later. Thus, these cells may represent an early, easily monitored cellular compartment that can predict the development of a long-lived antibody response to vaccines.

This could be a boon to the development of a more effective yearly influenza vaccine. “New annual influenza vaccines must be tested, and then manufactured, months in advance of the winter flu season,” Lund said. “This means we must make an educated guess as to which flu strain will be circulating the next winter.”

Why are vaccine candidates made so far in advance? Pharmaceutical companies, Lund says, need to wait many weeks after vaccinating volunteers to learn whether the new vaccine elicits a durable immune response that will last for months. “One potential outcome of the current study is we may have identified a new way to predict influenza vaccine durability that would give us an answer in days, rather than weeks or months,” Lund said. “If so, this type of early ‘biomarker’ could be used to test flu vaccines closer to flu season -; and moving that timeline might give us a better shot at predicting the right flu strain for the new annual vaccine.”

Seasonal flu kills 290,000 to 650,000 people each year, according to World Health Organization estimates. The global flu vaccine market was more than $5 billion in 2020.

To understand the Immunity study, it is useful to remember what happens when a vaccinated person subsequently encounters a flu virus.

Following exposure to previously encountered antigens, such as the hemagglutinin on inactivated influenza in flu vaccines, the immune system launches a recall response dominated by pre-existing memory B cells that can either produce new daughter cells or cells that can rapidly proliferate and differentiate into short-lived plasmablasts that produce antibodies to decrease morbidity and mortality. These latter B cells are called “effector” memory B cells.

“The best vaccines induce the formation of long-lived plasma cells and memory B cells,” said Lund, the Charles H. McCauley Professor in the UAB Department of Microbiology and director of the Immunology Institute. “Plasma cells live in your bone marrow and make protective antibodies that can be found in your blood, while memory B cells live for many years in your lymph nodes and in tissues like your lungs.

“Although plasma cells can survive for decades after vaccines like the measles vaccine, other plasma cells wane much more quickly after vaccination, as is seen with COVID-19,” Lund said. “If that happens, memory B cells become very important because these long-lived cells can rapidly respond to infection and can quickly begin making antibody.”

In the study, the UAB researchers looked at B cells isolated from blood of human volunteers who received flu vaccines over a span of three years, as well as B cells from tonsil tissue obtained after tonsillectomies.

They compared naïve B cells, FcRL5+ T-bet+ hemagglutinin-specific memory B cells, FcRL5neg T-betneg hemagglutinin-specific memory B cells and antibody secreting B cells, using standard phenotype profiling and single-cell RNA sequencing. They found that the FcRL5+ T-bet+ hemagglutinin-specific memory B cells were transcriptionally similar to effector-like memory cells, while the FcRL5neg T-betneg hemagglutinin-specific memory B cells exhibited stem-like central memory properties.

Antibody-secreting B cells need to produce a lot of energy to churn out antibody production, and they also must turn on processes that protect the cells from some of the detrimental side effects of that intense metabolism, including controlling the dangerous reactive oxygen species and boosting the unfolded protein response.

The FcRL5+ T-bet+ hemagglutinin-specific memory B cells did not express the plasma cell commitment factor, but did express transcriptional, epigenetic and metabolic functional programs that poised these cells for antibody production. These included upregulated genes for energy-intensive metabolic processes and cellular stress responses.

Accordingly, FcRL5+ T-bet+ hemagglutinin-specific memory B cells at Day 7 post-vaccination expressed intracellular immunoglobulin, a sign of early transition to antibody-secreting cells. Furthermore, human tonsil-derived FcRL5+ T-bet+ memory B differentiated more rapidly into antibody-secreting cells in vitro than did FcRL5neg T-betneg hemagglutinin-specific memory B cells.

Lund and Nellore, an associate professor in the UAB Department of Medicine Division of Infectious Diseases, are co-corresponding authors of the study, “A transcriptionally distinct subset of influenza-specific effector memory B cells predicts long-lived antibody responses to vaccination in humans.”

Co-authors with Lund and Nellore are Esther Zumaquero, R. Glenn King, Betty Mousseau, Fen Zhou and Alexander F. Rosenberg, UAB Department of Microbiology; Christopher D. Scharer, Tian Mi, Jeremy M. Boss, Christopher M. Tipton and Ignacio Sanz, Emory University School of Medicine, Atlanta, Georgia; Christopher F. Fucile, UAB Informatics Institute; John E. Bradley and Troy D. Randall, UAB Department of Medicine, Division of Clinical Immunology and Rheumatology; and Stuti Mutneja and Paul A. Goepfert, UAB Department of Medicine Division of Infectious Diseases.

Funding for the work came from National Institutes of Health grants AI125180, AI109962 and AI142737 and from the UAB Center for Clinical and Translational Science.

Source:

University of Alabama at Birmingham

Journal reference:

Nellore, A., et al. (2023). A transcriptionally distinct subset of influenza-specific effector memory B cells predicts long-lived antibody responses to vaccination in humans. Immunity. doi.org/10.1016/j.immuni.2023.03.001.

Microbiology

Nasal Vaccines: Stopping the COVID-19 Virus Before It Reaches the Lungs

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The Pfizer-BioNTech and Moderna mRNA vaccines have played a large role in preventing deaths and severe infections from COVID-19. But researchers are still in the process of developing alternative approaches to vaccines to improve their effectiveness, including how they’re administered. Immunologist and microbiologist Michael W. Russell of the University at Buffalo explains how nasal vaccines work, and where they are in the development pipeline.

The immune system has two distinct components: mucosal and circulatory.

The mucosal immune system provides protection at the mucosal surfaces of the body. These include the mouth, eyes, middle ear, the mammary and other glands, and the gastrointestinal, respiratory, and urogenital tracts. Antibodies and a variety of other anti-microbial proteins in the sticky secretions that cover these surfaces, as well as immune cells located in the lining of these surfaces, directly attack invading pathogens.

The circulatory part of the immune system generates antibodies and immune cells that are delivered through the bloodstream to the internal tissues and organs. These circulating antibodies do not usually reach the mucosal surfaces in large enough amounts to be effective. Thus mucosal and circulatory compartments of the immune system are largely separate and independent.

The immune components people may be most familiar with are proteins known as antibodies, or immunoglobulins. The immune system generates antibodies in response to invading agents that the body identifies as “non-self,” such as viruses and bacteria.

Antibodies bind to specific antigens: the part or product of a pathogen that induces an immune response. Binding to antigens allows antibodies to either inactivate them, as they do with toxins and viruses, or kill bacteria with the help of additional immune proteins or cells.

The mucosal immune system generates a specialized form of antibody called secretory IgA, or SIgA. Because SIgA is located in mucosal secretions, such as saliva, tears, nasal and intestinal secretions, and breast milk, it is resistant to digestive enzymes that readily destroy other forms of antibodies. It is also superior to most other immunoglobulins at neutralizing viruses and toxins, and at preventing bacteria from attaching to and invading the cells lining the surfaces of organs.

There are also many other key players in the mucosal immune system, including different types of anti-microbial proteins that kill pathogens, as well as immune cells that generate antibody responses.

Mucus is one of the central secretions of the mucosal immune system.

Almost all infectious diseases in people and other animals are acquired through mucosal surfaces, such as by eating or drinking, breathing or sexual contact. Major exceptions include infections from wounds, or pathogens delivered by insect or tick bites.

The virus that causes COVID-19, SARS-CoV-2, enters the body via droplets or aerosols that get into your nose, mouth, or eyes. It can cause severe disease if it descends deep into the lungs and causes an overactive, inflammatory immune response.

This means that the virus’s first contact with the immune system is probably through the surfaces of the nose, mouth, and throat. This is supported by the presence of SIgA antibodies against SARS-CoV-2 in the secretions of infected people, including their saliva, nasal fluid, and tears. These locations, especially the tonsils, have specialized areas that specifically trigger mucosal immune responses.

Some research suggests that if these SIgA antibody responses form as a result of vaccination or prior infection, or occur quickly enough in response to a new infection, they could prevent serious disease by confining the virus to the upper respiratory tract until it is eliminated.

Vaccines can be given through mucosal routes via the mouth or nose. This induces an immune response through areas that stimulate the mucosal immune system, leading mucosal secretions to produce SIgA antibodies.

There are several existing mucosal vaccines, most of them taken by mouth. Currently, only one, the flu vaccine, is delivered nasally.

In the case of nasal vaccines, the viral antigens intended to stimulate the immune system would be taken up by immune cells within the lining of the nose or tonsils. While the exact mechanisms by which nasal vaccines work in people have not been thoroughly studied, researchers believe they work analogously to oral mucosal vaccines. Antigens in the vaccine induce B cells in mucosal sites to mature into plasma cells that secrete a form of IgA. That IgA is then transported into mucosal secretions throughout the body, where it becomes SIgA.

If the SIgA antibodies in the nose, mouth or throat target SARS-CoV-2, they could neutralize the virus before it can drop down into the lungs and establish an infection.

Nasal vaccines could provide a more approachable alternative to injections for patients leery of needles.

I believe that arguably the best way to protect an individual against COVID-19 is to block the virus at its point of entry, or at least to confine it to the upper respiratory tract, where it might inflict relatively little damage.

Breaking chains of viral transmission is crucial to controlling epidemics. Researchers know that COVID-19 spreads during normal breathing and speech, and is exacerbated by sneezing, coughing, shouting, singing and other forms of exertion. Because these emissions mostly originate from saliva and nasal secretions, where the predominant form of antibody present is SIgA, it stands to reason that secretions with a sufficiently high level of SIgA antibodies against the virus could neutralize and thereby diminish its transmissibility.

Existing vaccines, however, do not induce SIgA antibody responses. Injected vaccines primarily induce circulating IgG antibodies, which are effective in preventing serious disease in the lungs. Nasal vaccines specifically induce SIgA antibodies in nasal and salivary secretions, where the virus is initially acquired, and can more effectively prevent transmission.

Nasal vaccines may be a useful supplement to injected vaccines in hot spots of infection. Since they don’t require needles, they might also help overcome vaccine hesitancy due to fear of injections.

There have been over 100 oral or nasal COVID-19 vaccines in development around the world.

Most of these have been or are currently being tested in animal models. Many have reported successfully inducing protective antibodies in the blood and secretions, and have prevented infection in these animals. However, few have been successfully tested in people. Many have been abandoned without fully reporting study details.

According to the World Health Organization, 14 nasal COVID-19 vaccines are in clinical trials as of late 2022. Reports from China and India indicate that nasal or inhaled vaccines have been approved in these countries. But little information is publicly available about the results of the studies supporting approval of these vaccines.

Written by Michael W. Russell, Professor Emeritus of Microbiology and Immunology, University at Buffalo.

This article was first published in The Conversation.The Conversation

Michael W. Russell, University at Buffalo

Microbiology

Scientists Warn of Spike in “Flesh-Eating” Infections in Parts of the U.S. Due to Climate Change

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Continued warming of the climate would see a rise in the number and spread of potentially fatal infections caused by bacteria found along parts of the coast of the United States.

Vibrio vulnificus bacteria grow in warm shallow coastal waters and can infect a cut or insect bite during contact with seawater. A new study led by the UK’s University of East Anglia (UEA) shows that the number of V. vulnificus infections along the East Coast of the US, a global hotspot for such infections, has gone up from 10 to 80 per year over a 30-year period.

In addition, every year cases occur further north. In the late 1980s, cases were found in the Gulf of Mexico and along the southern Atlantic coast but were rare north of Georgia. Today they can be found as far north as Philadelphia.

The researchers predict that by 2041–2060 infections may spread to encompass major population centers around New York. Combined with a growing and increasingly elderly population, who are more susceptible to infection, annual case numbers could double.

By 2081–2100, infections may be present in every Eastern US state under medium-to-high future emissions and warming scenarios.

The findings, published today (March 23, 2023) in the journal Scientific Reports, are important because although the number of cases in the US is not large, someone infected with V. vulnificus has a one-in-five chance of dying. It is also the most expensive marine pathogen in the US to treat.

The illness peaks in the summer and sees the bacteria spread rapidly and severely damage the person’s flesh. As a result, it is commonly called a ‘flesh-eating’ illness and many people who survive have had limbs amputated.

Lead author of the study Elizabeth Archer, a postgraduate researcher in UEA’s School of Environmental Sciences, said: “The projected expansion of infections highlights the need for increased individual and public health awareness in the areas affected. This is crucial as prompt action when symptoms occur is necessary to prevent major health consequences.

“Greenhouse gas emissions from human activity are changing our climate and the impacts may be especially acute on the world’s coastlines, which provide a major boundary between natural ecosystems and human populations and are an important source of human disease.

“We show that by the end of the 21st Century, V. vulnificus infections will extend further northwards but how far North will depend upon the degree of further warming and therefore on our future greenhouse gas emissions.

“If emissions are kept low, then cases may extend northwards only as far as Connecticut. If emissions are high, infections are predicted to occur in every US state on the East Coast. By the end of the 21st Century we predict that around 140-200 V. vulnificus infections may be reported each year.”

The research team suggests that individuals and health authorities could be warned in real time about particularly risky environmental conditions through marine or Vibrio specific early warning systems.

Active control measures could include greater awareness programmes for at risk groups, for example the elderly and individuals with underlying health conditions, and coastal signage during high-risk periods.

Co-author Prof Iain Lake from UEA said: “The observation that cases of V. vulnificus have expanded northwards along the East Coast of the US is an indication of the effect that climate change is already having on human health and the coastline. Knowing where cases are likely to occur in future should help health services plan for the future.”

The study is the first to map how the locations of V. vulnificus cases have changed along the eastern coastline of the US. It also the first to explore how climate change may influence the spread of cases in the future.

Information on where people caught V. vulnificus infection was obtained from the US Centers for Disease Control and Prevention. This allowed the team to map how cases of Vibrio vulnificus have extended northwards over 30 years from 1988-2018.

Temperature information based on observations and computer-based climate models were then used to predict where in the US cases might occur by the end of the 21st Century.

Co-author Prof James Oliver from the University of North Carolina Charlotte, in the US, said: “This is a landmark paper which not only ties global climate change to disease but provides strong evidence for the environmental spread of this extremely deadly bacterial pathogen.”

Reference: “Climate warming and increasing Vibrio vulnificus infections in North America” by Elizabeth Archer et al., 23 March 2023, Scientific Reports.
DOI: 10.1038/s41598-023-28247-2

University of East Anglia

Microbiology

Low-cost, universal oral COVID-19 vaccine prevents severe respiratory illness in hamsters

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Reviewed by Emily Henderson, B.Sc.Mar 22 2023

A UCLA-led team has developed an inexpensive, universal oral COVID-19 vaccine that prevented severe respiratory illness and weight loss when tested in hamsters, which are naturally susceptible to SARS-CoV-2. It proved as effective as vaccines administered by injection or intranasally in the research.

If ultimately approved for human use, it could be a weapon against all COVID-19 variants and boost uptake, particularly in low- and middle-income countries, and among those with an aversion to needles.

The study is published in the peer-reviewed journal Microbiology Spectrum.

The oral vaccine is based primarily on the nucleocapsid protein, which is the most abundantly expressed of the virus’s four major structural proteins and evolves at a much slower rate than the frequently mutating spike protein. The vaccine utilizes a highly weakened bacterium to produce the nucleocapsid protein in infected cells as well as the membrane protein, which is another highly abundant viral structural protein.

Being a universal vaccine based primarily upon the nucleocapsid protein, the vaccine is resistant to the incessant mutations of the SARS-CoV-2 spike protein upon which virtually all current vaccines are based. As a result, current vaccines rapidly become obsolete, requiring that they repeatedly be re-engineered. Hence, our vaccine should protect against new and emerging variants of SARS-CoV-2.”

Dr. Marcus Horwitz, senior author, distinguished professor of medicine in the Division of Infectious Diseases and of microbiology, immunology and molecular genetics at the David Geffen School of Medicine at UCLA

Oral delivery also makes it easier to distribute the vaccine in resource poor areas of the world by eliminating the need for needles, syringes, and trained personnel to deliver injectable vaccines, he added. “An oral vaccine may also be attractive to many people with vaccine hesitancy on account of fear of needles.”

The researchers noted that while it worked exceptionally well in preventing severe respiratory illness, it did not provide full protection against high viral loads in the hamsters. Also, they did not test it against the Omicron strain, which contains a nearly identical nucleocapsid protein, because of this strain’s low virulence in the golden Syrian hamsters they used.

But the vaccine, they write, “is efficacious when administered via the oral route against COVID-19-like disease in a highly demanding animal model. This conveniently administered, easily manufactured, inexpensive, and readily stored and transported vaccine could play a major role in ending the COVID-19 pandemic by protecting immunized individuals from serious disease from current and future strains of SARS-CoV-2.”

The next step in the process will be to manufacture the vaccine for oral administration via an acid-resistant enteric capsule that will allow the vaccine to be safely released in the small intestine, Horwitz said. It will then be tested for safety, immunogenicity, and efficacy in humans.

“We also plan to expand the vaccine to protect against infections caused by other types of potentially pandemic coronaviruses such as the virus that causes Middle Eastern Respiratory Syndrome (MERS),” he added.

Additional authors are Qingmei Jia and Saša Masleša-Galić of UCLA; Helle Bielefeldt-Ohmann of the University of Queensland, Australia; and Rachel Maison, Airn Hartwig, and Richard Bowen of Colorado State University.

This study was supported by a Corona Virus Seed grant from the UCLA AIDS Institute and Charity Treks and by the National Institutes of Health (AI141390).

Source:

UCLA Health

Journal reference:

Jia, Q., et al. (2023). Oral Administration of Universal Bacterium-Vectored Nucleocapsid-Expressing COVID-19 Vaccine is Efficacious in Hamsters. Microbiology Spectrum. doi.org/10.1128/spectrum.05035-22.

Microbiology

Vaginal sex can shape the composition of urethral microbiome in healthy men

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Reviewed by Emily Henderson, B.Sc.Mar 21 2023

Contrary to common beliefs, your urine is not germ free. In fact, a new study shows that the urethra of healthy men is teeming with microbial life and that a specific activity-;vaginal sex-;can shape its composition. The research, published March 24 in the journal Cell Reports Medicine, provides a healthy baseline for clinicians and scientists to contrast between healthy and diseased states of the urethra, an entrance to the urinary and reproductive systems.

We know where bugs in the gut come from; they primarily come from our surroundings through fecal-oral transfer. But where does genital microbiology come from?”

David Nelson, co-senior author, microbiologist at Indiana University

To flush out the answer, the team of microbiologists, statisticians, and physicians sequenced the penile urethra swabs of 110 healthy adult men. These participants had no urethral symptoms or sexually transmitted infections (STIs) and no inflammation of the urethra. DNA sequencing results revealed that two types of bacterial communities call the penile urethra home-;one native to the organ, the other from a foreign source.

“It is important to set this baseline,” says co-senior author Qunfeng Dong, a bioinformatician at Loyola University Chicago. “Only by understanding what health is can we define what diseases are.”

The researchers found that most of the healthy men had a simple, sparse community of oxygen-loving bacteria in the urethra. In addition, these bacteria probably live close to the urethral opening at the tip of the penis, where there is ample oxygen. The consistent findings of these bacteria suggest that they are the core community that supports penile urethra health.

But some of the men also had a more complex secondary group of bacteria that are often found in the vagina and can disturb the healthy bacterial ecosystem of the vagina. The team speculates that these bacteria reside deeper in the penile urethra because they thrive in oxygen-scarce settings. Only men who reported having vaginal sex carry these bacteria, hinting at the microbes’ origins.

Delving into the participant’s sexual history, the team found a close link between this second bacterial community and vaginal sex but not other sexual behaviors, such as oral sex and anal sex. They also found evidence that vaginal sex has lasting effects. Vagina-associated bacteria remained detectable in the participants for at least two months after vaginal sex, indicating that sexual exposure to the vagina can reshape the male urinary-tract microbiome.

“In our study, one behavior explains 10% of the overall bacterial variation,” says Nelson, when discussing the influence of vaginal sex. “The fact that a specific behavior is such a strong determinant is just profound.”

Although current findings from the study show that vaginal bacteria can spread to the penile urethra, the team’s next plan is to test whether the reverse is true. Using the newly established baseline, the researchers also hope to offer new insights into bacteria’s role in urinary- and reproductive-tract diseases, including unexplained urethral inflammation and STIs.

“STIs really impact people who are socioeconomically disadvantaged; they disproportionately impact women and minorities,” says Nelson. “It’s a part of health care that’s overlooked because of stigma. I think our study has a potential to dramatically change how we handle STI diagnosis and management in a positive way.”

This work was supported by the National Institute of Allergy and Infectious Diseases.

Source:

Cell Press

Journal reference:

Toh, E., et al. (2023). Sexual behavior shapes male genitourinary microbiome composition. Cell Reports Medicine. doi.org/10.1016/j.xcrm.2023.100981

Microbiology

New, Better Models Show How Infectious Diseases Like COVID-19 Spread

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The COVID-19 pandemic has emphasized the significance of modeling in comprehending the spread of diseases and in providing crucial insights into disease prevention and control. A new model has utilized COVID-19 data and combined two classic methodologies to enhance predictions about disease spread.

A widely used modeling technique involves dividing the population into compartments, such as susceptible (S), infected (I), and recovered (R), in what is known as the SIR model. This approach models the rates of change that describe the movement of individuals from one compartment to another.

KAUST researchers, led by Paula Moraga, integrated SIR compartment modeling in time and a point process modeling approach in space–time, while also taking into account age-specific contact patterns. To do this, they used a two-step framework that allowed them to model data on infectious locations over time for different age groups.

“The model gives more accurate predictions than previous approaches when making short/mid-range predictions in space and time,” says lead researcher André Amaral.

“It also accounts for different age classes so we can treat these groups separately, resulting in finer control over the number of infectious cases.”

Their approach paid off. In a simulation study to assess the model’s performance, and in a case study of COVID-19 cases in Cali, Colombia, the model performed better when making predictions and provided similar results for past time points, compared with models commonly used in predictive modeling.

“The model’s features can help decision-makers to identify high-risk locations and vulnerable populations to develop better strategies for disease control,” says Amaral.

It also can be used with any infectious disease that fits the compartment model assumptions, such as influenza. Furthermore, the model can account for different age groups and their associated contact patterns, meaning it allows more detailed conclusions about where, when, and to which population group decision-makers should focus their resources if they want to control disease spread.

“In future work, we might extend such an approach and use different temporal models to replace the SIR model. This would allow us to account for different epidemic dynamics and expand the number of scenarios that the model can be used for,” says Amaral.

“Finally, to improve the model’s predictive capabilities, we might work on developing ensemble approaches that combine a number of predictions from a number of different models and also account for potential time delays in collecting data,” he adds.

Moraga says the model’s performance demonstrates the importance of quality and detailed data by location, time, and population group to understand infectious disease dynamics while highlighting the need to strengthen national surveillance systems to improve public health decision-making.

Reference: “Spatio-temporal modeling of infectious diseases by integrating compartment and point process models” by André Victor Ribeiro Amaral, Jonatan A. González and Paula Moraga, 13 December 2022, Stochastic Environmental Research and Risk Assessment.
DOI: 10.1007/s00477-022-02354-4

King Abdullah University of Science & Technology (KAUST)

Microbiology

CDC Warns of Deadly Fungus Spreading at Alarming Rate in U.S. Healthcare Facilities

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Candida auris (C. auris), an emerging fungus considered an urgent antimicrobial resistance (AR) threat, spread at an alarming rate in U.S. healthcare facilities in 2020-2021, according to data from the Centers for Disease Control and Prevention (CDC) published in the Annals of Internal Medicine. Equally concerning was a tripling in 2021 of the number of cases that were resistant to echinocandins, the antifungal medicine most recommended for treatment of C. auris infections. In general, C. auris is not a threat to healthy people. People who are very sick, have invasive medical devices, or have long or frequent stays in healthcare facilities are at increased risk for acquiring C. auris. CDC has deemed C. auris as an urgent AR threat, because it is often resistant to multiple antifungal drugs, spreads easily in healthcare facilities, and can cause severe infections with high death rates.

“The rapid rise and geographic spread of cases is concerning and emphasizes the need for continued surveillance, expanded lab capacity, quicker diagnostic tests, and adherence to proven infection prevention and control,” said CDC epidemiologist Dr. Meghan Lyman, lead author of the paper.

As further explained in the article, C. auris has spread in the United States since it was first reported in 2016, with a total of 3,270 clinical cases (in which infection is present) and 7,413 screening cases (in which the fungus is detected but not causing infection) reported through December 31, 2021. Clinical cases have increased each year since 2016, with the most rapid rise occurring during 2020-2021. CDC has continued to see an increase in case counts for 2022. During 2019-2021, 17 states identified their first C. auris case ever. Nationwide, clinical cases rose from 476 in 2019 to 1,471 in 2021. Screening cases tripled from 2020 to 2021, for a total of 4,041. Screening is important to prevent spread by identifying patients carrying the fungus so that infection prevention controls can be used.

C. auris case counts have increased for many reasons, including poor general infection prevention and control (IPC) practices in healthcare facilities. Case counts may also have increased because of enhanced efforts to detect cases, including increased colonization screening, a test to see if someone has the fungus somewhere on their body but does not have an infection or symptoms of infection. The timing of this increase and findings from public health investigations suggest C. auris spread may have worsened due to strain on healthcare and public health systems during the COVID-19 pandemic.

The CDC’s Antimicrobial Resistance Laboratory Network, which provides nationwide lab capacity to rapidly detect antimicrobial resistance and inform local responses to prevent spread and protect people, provided some of the data for this report. CDC worked to significantly strengthen laboratory capacity, including in state, territorial, and local health departments, through supplemental funding supported by the American Rescue Plan Act. These efforts include increasing susceptibility testing capacity for C. auris from seven Regional Labs to more than 26 labs nationwide.

CDC continues to work with state, local, and territorial health departments and other partners to address this emerging threat to public health. Review more information on C. auris, the Antimicrobial Resistance Threats Report that identified C. auris as an urgent threat in the United States, or the WHO fungal priority pathogen list that identifies C. auris as a priority globally.

Reference: “Worsening Spread of Candida auris in the United States, 2019 to 2021” by Meghan Lyman, MD, Kaitlin Forsberg, MPH, D. Joseph Sexton, PhD, Nancy A. Chow, PhD, MS, Shawn R. Lockhart, PhD, Brendan R. Jackson, MD, MPH and Tom Chiller, MD, MPHTM, 21 March 2023, Annals of Internal Medicine.
DOI: 10.7326/M22-3469

Centers for Disease Control and Prevention

Microbiology

SARS-CoV-2 infection damages the CD8+ T cell response to vaccination

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Reviewed by Emily Henderson, B.Sc.Mar 20 2023

The magnitude and quality of a key immune cell’s response to vaccination with two doses of the Pfizer-BioNTech COVID-19 vaccine were considerably lower in people with prior SARS-CoV-2 infection compared to people without prior infection, a study has found. In addition, the level of this key immune cell that targets the SARS-CoV-2 spike protein was substantially lower in unvaccinated people with COVID-19 than in vaccinated people who had never been infected. Importantly, people who recover from SARS-CoV-2 infection and then get vaccinated are more protected than people who are unvaccinated. These findings, which suggest that the virus damages an important immune-cell response, were published today in the journal Immunity.

The study was co-funded by the National Institute of Allergy and Infectious Diseases (NIAID), part of the National Institutes of Health, and led by Mark M. Davis, Ph.D. Dr. Davis is the director of the Stanford Institute for Immunity, Transplantation and Infection and a professor of microbiology and immunology at Stanford University School of Medicine in Palo Alto, California. He is also a Howard Hughes Medical Institute Investigator.

Dr. Davis and colleagues designed a very sensitive tool to analyze how immune cells called CD4+ T cells and CD8+ T cells respond to SARS-CoV-2 infection and vaccination. These cells coordinate the immune system’s response to the virus and kill other cells that have been infected, helping prevent COVID-19. The tool was designed to identify T cells that target any of dozens of specific regions on the virus’s spike protein as well as some other viral regions. The Pfizer-BioNTech vaccine uses parts of the SARS-CoV-2 spike protein to elicit an immune response without causing infection.

The investigators studied CD4+ and CD8+ T-cell responses in blood samples from three groups of volunteers. One group had never been infected with SARS-CoV-2 and received two doses of the Pfizer-BioNTech COVID-19 vaccine. The second group had previously been infected with SARS-CoV-2 and received two doses of the vaccine. The third group had COVID-19 and was unvaccinated.

The researchers found that vaccination of people who had never been infected with SARS-CoV-2 induced robust CD4+ and CD8+ T-cell responses to the virus’ spike protein. In addition, these T cells produced multiple types of cell-signaling molecules called cytokines, which recruit other immune cells—including antibody-producing B cells—to fight pathogens. However, people who had been infected with SARS-CoV-2 prior to vaccination produced spike-specific CD8+ T cells at considerably lower levels—and with less functionality—than vaccinated people who had never been infected. Moreover, the researchers observed substantially lower levels of spike-specific CD8+ T cells in unvaccinated people with COVID-19 than in vaccinated people who had never been infected.

Taken together, the investigators write, these findings suggest that SARS-CoV-2 infection damages the CD8+ T cell response, an effect akin to that observed in earlier studies showing long-term damage to the immune system after infection with viruses such as hepatitis C or HIV. The new findings highlight the need to develop vaccination strategies to specifically boost antiviral CD8+ T cell responses in people previously infected with SARS-CoV-2, the researchers conclude.  

Source:

National Institutes of Health

Journal reference:

Gao, F., et al. (2023). Robust T cell responses to Pfizer/BioNTech vaccine compared to infection and evidence of attenuated peripheral CD8+ T cell responses due to COVID-19. Immunity. doi.org/10.1016/j.immuni.2023.03.005.

Microbiology

New SARS-CoV-2 Omicron XBB.1.5 variant has high transmissibility and infectivity, study finds

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Mar 20 2023Reviewed by Danielle Ellis, B.Sc.

COVID-19 has caused significant global panic after its rapid emergence more than 3 years ago. Although we now have highly effective vaccines against the SARS-CoV-2 virus, which causes COVID-19, scientists continue to study emerging SARS-CoV-2 variants in order to safeguard public health and devise global preventive strategies against emerging variants. A team led by Japanese researchers has recently discovered that the SARS-CoV-2 Omicron XBB.1.5 variant, prevalent in the Western hemisphere, has high transmissibility and infectivity.

New SARS-CoV-2 Omicron XBB.1.5 variant has high transmissibility and infectivity, study finds
New SARS-CoV-2 variant may jeopardize public health across the globe. The SARS-CoV-2 Omicron XBB.1.5 variant spreads rapidly and is more infectious than its historic precursor. Image Credit: The University of Tokyo

Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) has been responsible for millions of deaths worldwide. Although scientists have designed novel vaccines to counter COVID-19, they are constantly on the lookout for emerging variants that can bypass vaccine resistance and potentially jeopardize global public health. A team led by Japanese researchers has recently been successful in characterizing the new SARS-CoV-2 Omicron XBB.1.5 variant, which was first detected in October 2022. Their findings were published on January 31, 2023 in volume 23 of The Lancet Infectious Diseases.​​​

Says senior author Prof. Kei Sato from the Division of Systems Virology, The Institute of Medical Science, The University of Tokyo, Japan, “Because the Omicron XBB.1.5 variant can spread more rapidly than previous variants and has a potential to cause the next epidemic surge, we should carefully monitor it to safeguard public health.”

While studying emerging variants of the SARs-CoV-2 Omicron lineage, the research team made a startling discovery: the SARS-CoV-2 Omicron XBB.1.5 variant has a novel mutation in the spike (S) protein—the protein that anchors the virus firmly to the human angiotensin converting enzyme-2 (ACE2) receptor, thus facilitating the invasion of human cells. The serine-to-proline amino acid mutation noted at residue no. 486 in the S protein is virologically concerning because of a variety of reasons.

Sharing his concerns, first author Keiya Uriu from the Division of Systems Virology, Department of Microbiology and Immunology, The University of Tokyo, Japan, says, “In late 2022, the SARS-CoV-2 Omicron BQ.1 and XBB lineages, characterized by amino acid substitutions in the S protein and increased viral fitness, had become predominant in the Western and Eastern Hemisphere, respectively. In 2022, we elucidated the characteristics of a variety of newly emerging SARS-CoV-2 Omicron subvariants. At the end of 2022, the XBB.1.5 variant, a descendant of XBB.1 that acquired the S:S486P substitution, emerged and was rapidly spreading in the USA.”

To gain mechanistic insights into the infectivity, transmissibility, and immune response associated with XBB.1.5, the team conducted a series of experiments. For instance, upon conducting epidemic dynamics analysis—statistical modeling that facilitates the analysis of the general characteristics of any epidemic—the team realized that the relative effective reproduction number (Re) of XBB.1.5 was 1.2-fold greater than that of the parental XBB.1. This indicated that an individual with the XBB.1.5 variant could infect 1.2 times more people in the population than someone with the parental XBB.1 variant. Moreover, the team also realized that, as of December 2022, XBB.1.5 was rapidly outcompeting BQ.1.1, the predominant lineage in the United States.

Co-first-author Jumpei Ito from the Division of Systems Virology, remarks, “Our data suggest that XBB.1.5 will rapidly spread worldwide in the near future.”

The team also studied the virological features of XBB.1.5 to determine how tightly the S protein of the new variant interacts with the human ACE2 receptor. To this end, the researchers conducted a yeast surface display assay. The results showed that the dissociation constant (KD) corresponding to the physical interaction between the XBB.1.5 S receptor-binding domain (RBD) and the human ACE2 receptor is significantly (4.3-fold) lower than that for XBB.1 S RBD. “In other words, the XBB.1.5 variant binds to human ACE2 receptor with very high affinity,” explains Shigeru Fujita from the Division of Systems Virology.

Further experiments using lentivirus-based pseudoviruses also showed that XBB.1.5 had approximately 3-fold higher infectivity than XBB.1. These results suggest that XBB.1.5 exhibits a remarkably strong affinity to the human ACE2 receptor, which can be attributed to the S486P substitution.

The study by Prof. Sato and his team led to another important discovery from an immunization perspective. The XBB.1.5 S protein was found to be highly resistant to neutralization antibodies elicited by breakthrough infection with the BA.2/BA.5 subvariants. In other words, patients with prior infection from the BA.2/BA.5 subvariants may not show robust immunity against XBB.1.5, increasing their chances of infection and disease.

The results of our virological experiments explain why the Omicron XBB.1.5 variant has a higher transmissibility than past variants: This variant acquired strong binding ability to human ACE2 while maintaining a higher ability to escape from neutralizing antibodies.”

​​​​​​​Yusuke Kosugi, Division of Systems Virology, Department of Microbiology and Immunology, The University of Tokyo, Japan

Contributing members of The Genotype to Phenotype Japan (G2P-Japan) Consortium conclude, “The SARS-CoV-2 Omicron XBB.1.5 variant does show enhanced transmissibility. Although few cases have been detected in the Eastern hemisphere, it could become a looming threat. Imminent prevention measures are needed.”

​​​​​​​Thanks to the research team for the early warning! Meanwhile, we must continue adopting safe practices to defend ourselves from XBB.1.5. 

Source:

The University of Tokyo

Journal reference:

Uriu, K., et al. (2023) Enhanced transmissibility, infectivity, and immune resistance of the SARS-CoV-2 omicron XBB.1.5 variant. The Lancet Infectious Diseases. doi.org/10.1016/S1473-3099(23)00051-8.