Phenotyping male infertility in the mouse: how to get the most out of a ‘non-performer’

BACKGROUND: Functional male gametes are produced through complex processes that take place within the testis, epididymis and female reproductive tract. A breakdown at any of these phases can result in male infertility. The production of mutant mouse models often yields an unexpected male infertility phenotype. It is with this in mind that the current review has been written. The review aims to act as a guide to the 'non-reproductive biologist' to facilitate a systematic analysis of sterile or subfertile mice and to assist in extracting the maximum amount of information from each model. METHODS: This is a review of the original literature on defects in the processes that take a mouse spermatogonial stem cell through to a fully functional spermatozoon, which result in male infertility. Based on literature searches and personal experience, we have outlined a step-by-step strategy for the analysis of an infertile male mouse line. RESULTS: A wide range of methods can be used to define the phenotype of an infertile male mouse. These methods range from histological methods such as electron microscopy and immunohistochemistry, to hormone analyses and methods to assess sperm maturation status and functional competence. CONCLUSION: With the increased rate of genetically modified mouse production, the generation of mouse models with unexpected male infertility is increasing. This manuscript will help to ensure that the maximum amount of information is obtained from each mouse model and, by extension, will facilitate the knowledge of both normal fertility processes and the causes of human infertility

Mortality and pulmonary complications in patients undergoing surgery with perioperative SARS-CoV-2 infection: an international cohort study

Background: The impact of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) on postoperative recovery needs to be understood to inform clinical decision making during and after the COVID-19 pandemic. This study reports 30-day mortality and pulmonary complication rates in patients with perioperative SARS-CoV-2 infection. Methods: This international, multicentre, cohort study at 235 hospitals in 24 countries included all patients undergoing surgery who had SARS-CoV-2 infection confirmed within 7 days before or 30 days after surgery. The primary outcome measure was 30-day postoperative mortality and was assessed in all enrolled patients. The main secondary outcome measure was pulmonary complications, defined as pneumonia, acute respiratory distress syndrome, or unexpected postoperative ventilation. Findings: This analysis includes 1128 patients who had surgery between Jan 1 and March 31, 2020, of whom 835 (74·0%) had emergency surgery and 280 (24·8%) had elective surgery. SARS-CoV-2 infection was confirmed preoperatively in 294 (26·1%) patients. 30-day mortality was 23·8% (268 of 1128). Pulmonary complications occurred in 577 (51·2%) of 1128 patients; 30-day mortality in these patients was 38·0% (219 of 577), accounting for 81·7% (219 of 268) of all deaths. In adjusted analyses, 30-day mortality was associated with male sex (odds ratio 1·75 [95% CI 1·28–2·40], p\textless0·0001), age 70 years or older versus younger than 70 years (2·30 [1·65–3·22], p\textless0·0001), American Society of Anesthesiologists grades 3–5 versus grades 1–2 (2·35 [1·57–3·53], p\textless0·0001), malignant versus benign or obstetric diagnosis (1·55 [1·01–2·39], p=0·046), emergency versus elective surgery (1·67 [1·06–2·63], p=0·026), and major versus minor surgery (1·52 [1·01–2·31], p=0·047). Interpretation: Postoperative pulmonary complications occur in half of patients with perioperative SARS-CoV-2 infection and are associated with high mortality. Thresholds for surgery during the COVID-19 pandemic should be higher than during normal practice, particularly in men aged 70 years and older. Consideration should be given for postponing non-urgent procedures and promoting non-operative treatment to delay or avoid the need for surgery. Funding: National Institute for Health Research (NIHR), Association of Coloproctology of Great Britain and Ireland, Bowel and Cancer Research, Bowel Disease Research Foundation, Association of Upper Gastrointestinal Surgeons, British Association of Surgical Oncology, British Gynaecological Cancer Society, European Society of Coloproctology, NIHR Academy, Sarcoma UK, Vascular Society for Great Britain and Ireland, and Yorkshire Cancer Research

Stepping dynamics of the bacterial flagellar motor and F1-ATPase

Rotary molecular motors are protein complexes which convert chemical or electrochemical energy from the environment into mechanical work in the form of rotary motion. The work in this thesis examines two of these motors: the F1 portion of F1FO- ATP synthase, which is responsible for ATP production in bacteria and eukaryotes, and the bacterial flagellar motor (BFM), which rotates the flagella of a bacterium, enabling locomotion. The aim of these investigations was to measure the stepping dynamics of these motors, in order to further elucidate details of the stepping mechanism, the mechanism of rotation, and the mechanochemical cycle. A back-scattering laser dark field microscope of unprecedented resolution was designed and constructed to observe the rotation of gold nanoparticles attached to fixed motors. This micro- scope is capable of sub-nanometer and 20μs resolution. The protocols and algorithms to collect and analyze high resolution rotational data developed for these experiments have yielded novel discoveries for both F1 and the BFM. While most of the previous single-molecule work has been done on F1 from the thermophilic Bacilus PS3 (TF1), only mitochondrial F1 has been well characterized by high-resolution crystal structures, and single-molecule studies of mesophilic F1 are lacking. This thesis presents evidence that mesophilic F1 from E. coli and wild type yeast F1 from S. cerevisiae are governed by the same mechanism as TF1 under laboratory conditions. Experiments with yeast F1 mutants allow a direct comparison between single-molecule rotation studies and high resolution crystal structures. A data set of unprecedented size and resolution was acquired of high speed, low load BFM rotation, enabling the first observation of steps in the BFM under physiological conditions. Preliminary results from this analysis question previously published results of the dependence of speed on stator number at low load and provide novel hypotheses necessitating new models of BFM rotation.</p

Stepping Dynamics of the Bacterial Flagellar Motor and F₁-ATPase

Rotary molecular motors are protein complexes which convert chemical or electrochemical energy from the environment into mechanical work in the form of rotary motion. The work in this thesis examines two of these motors: the F1 portion of F1FO- ATP synthase, which is responsible for ATP production in bacteria and eukaryotes, and the bacterial flagellar motor (BFM), which rotates the flagella of a bacterium, enabling locomotion. The aim of these investigations was to measure the stepping dynamics of these motors, in order to further elucidate details of the stepping mechanism, the mechanism of rotation, and the mechanochemical cycle. A back-scattering laser dark field microscope of unprecedented resolution was designed and constructed to observe the rotation of gold nanoparticles attached to fixed motors. This micro- scope is capable of sub-nanometer and 20μs resolution. The protocols and algorithms to collect and analyze high resolution rotational data developed for these experiments have yielded novel discoveries for both F1 and the BFM. While most of the previous single-molecule work has been done on F1 from the thermophilic Bacilus PS3 (TF1), only mitochondrial F1 has been well characterized by high-resolution crystal structures, and single-molecule studies of mesophilic F1 are lacking. This thesis presents evidence that mesophilic F1 from E. coli and wild type yeast F1 from S. cerevisiae are governed by the same mechanism as TF1 under laboratory conditions. Experiments with yeast F1 mutants allow a direct comparison between single-molecule rotation studies and high resolution crystal structures. A data set of unprecedented size and resolution was acquired of high speed, low load BFM rotation, enabling the first observation of steps in the BFM under physiological conditions. Preliminary results from this analysis question previously published results of the dependence of speed on stator number at low load and provide novel hypotheses necessitating new models of BFM rotation.This thesis is not currently available on ORA

Editorial: Flagellar Motors and Force Sensing in Bacteria

International audienc

The Dynamic Ion Motive Force Powering the Bacterial Flagellar Motor

International audienceThe bacterial flagellar motor (BFM) is a rotary molecular motor embedded in the cell membrane of numerous bacteria. It turns a flagellum which acts as a propeller, enabling bacterial motility and chemotaxis. The BFM is rotated by stator units, inner membrane protein complexes that stochastically associate to and dissociate from individual motors at a rate which depends on the mechanical and electrochemical environment. Stator units consume the ion motive force (IMF), the electrochemical gradient across the inner membrane that results from cellular respiration, converting the electrochemical energy of translocated ions into mechanical energy, imparted to the rotor. Here, we review some of the main results that form the base of our current understanding of the relationship between the IMF and the functioning of the flagellar motor. We examine a series of studies that establish a linear proportionality between IMF and motor speed, and we discuss more recent evidence that the stator units sense the IMF, altering their rates of dynamic assembly. This, in turn, raises the question of to what degree the classical dependence of motor speed on IMF is due to stator dynamics vs. the rate of ion flow through the stators. Finally, while long assumed to be static and homogeneous, there is mounting evidence that the IMF is dynamic, and that its fluctuations control important phenomena such as cell-to-cell signaling and mechanotransduction. Within the growing toolbox of single cell bacterial electrophysiology, one of the best tools to probe IMF fluctuations may, ironically, be the motor that consumes it. Perfecting our incomplete understanding of how the BFM employs the energy of ion flow will help decipher the dynamical behavior of the bacterial IMF

A simple low-cost device enables four epi-illumination techniques on standard light microscopes

Back-scattering darkfield (BSDF), epi-fluorescence (EF), interference reflection contrast (IRC), and darkfield surface reflection (DFSR) are advanced but expensive light microscopy techniques with limited availability. Here we show a simple optical design that combines these four techniques in a simple low-cost miniature epi-illuminator, which inserts into the differential interference-contrast (DIC) slider bay of a commercial microscope, without further additions required. We demonstrate with this device: 1) BSDF-based detection of Malarial parasites inside unstained human erythrocytes; 2) EF imaging with and without dichroic components, including detection of DAPI-stained Leishmania parasite without using excitation or emission filters; 3) RIC of black lipid membranes and other thin films, and 4) DFSR of patterned opaque and transparent surfaces. We believe that our design can expand the functionality of commercial bright field microscopes, provide easy field detection of parasites and be of interest to many users of light microscopy