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1. Distinct cytoskeletal proteins define zones of enhanced cell wall synthesis in Helicobacter pylori

   https://doi.org/10.7554/eLife.52482  

   Taylor, Jennifer A; Bratton, Benjamin P; Sichel, Sophie R; Blair, Kris M; Jacobs, Holly M; DeMeester, Kristen E; Kuru, Erkin; Gray, Joe; Biboy, Jacob; VanNieuwenhze, Michael S; et al (January 2020, eLife)

   Round spheres, straight rods, and twisting corkscrews, bacteria come in many different shapes. The shape of bacteria is dictated by their cell wall, the strong outer barrier of the cell. As bacteria grow and multiply, they must add to their cell wall while keeping the same basic shape. The cells walls are made from long chain-like molecules via processes that are guided by protein scaffolds within the cell. Many common antibiotics, including penicillin, stop bacterial infections by interrupting the growth of cell walls. Helicobacter pylori is a common bacterium that lives in the gut and, after many years, can cause stomach ulcers and stomach cancer. H. pylori are shaped in a twisting helix, much like a corkscrew. This shape helps H. pylori to take hold and colonize the stomach. It remains unclear how H. pylori creates and maintains its helical shape. The helix is much more curved than other bacteria, and H. pylori does not have the same helpful proteins that other curved bacteria do. If H. pylori grows asymmetrically, adding more material to the cell wall on its long outer side to create a twisting helix, what controls the process? To find out, Taylor et al. grew H. pylori cells and watched how the cell walls took shape. First, a fluorescent dye was attached to the building blocks of the cell wall or to underlying proteins that were thought to help direct its growth. The cells were then imaged in 3D, and images from hundreds of cells were reconstructed to analyze the growth patterns of the bacteria’s cell wall. A protein called CcmA was found most often on the long side of the twisting H. pylori. When the CcmA protein was isolated in a dish, it spontaneously formed sheets and helical bundles, confirming its role as a structural scaffold for the cell wall. When CcmA was absent from the cell of H. pylori, Taylor et al. observed that the pattern of cell growth changed substantially. This work identifies a key component directing the growth of the cell wall of H. pylori and therefore, a new target for antibiotics. Its helical shape is essential for H. pylori to infect the gut, so blocking the action of the CcmA protein may interrupt cell wall growth and prevent stomach infections. 

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2. Peptidoglycan precursor synthesis along the sidewall of pole-growing mycobacteria

   https://doi.org/10.7554/eLife.37243  

   García-Heredia, Alam; Pohane, Amol Arunrao; Melzer, Emily S; Carr, Caleb R; Fiolek, Taylor J; Rundell, Sarah R; Chuin Lim, Hoong; Wagner, Jeffrey C; Morita, Yasu S; Swarts, Benjamin M; et al (September 2018, eLife)

   Rod-shaped mycobacteria expand from their poles, yet d-amino acid probes label cell wall peptidoglycan in this genus at both the poles and sidewall. We sought to clarify the metabolic fates of these probes. Monopeptide incorporation was decreased by antibiotics that block peptidoglycan synthesis or l,d-transpeptidation and in an l,d-transpeptidase mutant. Dipeptides complemented defects in d-alanine synthesis or ligation and were present in lipid-linked peptidoglycan precursors. Characterizing probe uptake pathways allowed us to localize peptidoglycan metabolism with precision: monopeptide-marked l,d-transpeptidase remodeling and dipeptide-marked synthesis were coincident with mycomembrane metabolism at the poles, septum and sidewall. Fluorescent pencillin-marked d,d-transpeptidation around the cell perimeter further suggested that the mycobacterial sidewall is a site of cell wall assembly. While polar peptidoglycan synthesis was associated with cell elongation, sidewall synthesis responded to cell wall damage. Peptidoglycan editing along the sidewall may support cell wall robustness in pole-growing mycobacteria. 

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3. Oleaginous Fungi in Biorefineries

   https://doi.org/10.1016/B978-0-12-819990-9.00004-4  

   Zhu S, Bonito G (January 2020, Reference Module in Life Sciences)

   null (Ed.)

   Many unicellular microorganisms including yeasts, fungi, microalgae, and to a lesser extent bacteria (Fig. 1), can produce intra- cellular edible oils under normal and specialized conditions (Papanikolaou and Aggelis, 2011). Most of these organisms can accumulate microbial lipids, or single-cell oils (SCOs), to 20%–90% (w/w) of their dry cell biomass. For example, fungi in the genus Mortierella and Umbelopsis can accumulate lipids at concentrations that exceed 86% of their dry weight (Meng et al., 2009). Microbial lipids can be produced using low-priced organic materials, including waste-streams from the food industry, as growth substrate. The fatty acid of microbial lipids is very similar to the conventional vegetable oils in type and composition (Madani et al., 2017). Furthermore, microbial lipids have many potential applications, including human food additives, nutraceuticals, pharmaceuticals, cosmetics, biopolymers and feed ingredients for aquaculture, and as an alternative feedstock for the production of biofuel (Lewis et al., 2000). Due to the reduced availability of cultivable land and increasing human population growth, producing lipids via traditional methods will not satisfy the rapidly growing global demand. Therefore, microbial lipids accu- mulated from microorganisms, especially oleaginous fungi, are considered as a vital and renewable oil resource and have been regarded as an alternative to animal and plant lipids in recent years, given their unique characteristics and functions in energy, chemical, and food industries (Huang et al., 2017). The production of microbial lipids is particularly attractive when low or negative cost substrates are used as the feedstock. 

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4. Members of the ELMOD protein family specify formation of distinct aperture domains on the Arabidopsis pollen surface

   https://doi.org/10.7554/eLife.71061  

   Zhou, Yuan; Amom, Prativa; Reeder, Sarah H; Lee, Byung Ha; Helton, Adam; Dobritsa, Anna A (September 2021, eLife)

   Zooming in on cells reveals patterns on their outer surfaces. These patterns are actually a collection of distinct areas of the cell surface, each containing specific combinations of molecules. The outer layers of pollen grains consist of a cell wall, and a softer cell membrane that sits underneath. As a pollen grain develops, it recruits certain fats and proteins to specific areas of the cell membrane, known as ‘aperture domains’. The composition of these domains blocks the cell wall from forming over them, leading to gaps in the wall called ‘pollen apertures’. Pollen apertures can open and close, aiding reproduction and protecting pollen grains from dehydration. The number, location, and shape of pollen apertures vary between different plant species, but are consistent within the same species. In the plant species Arabidopsis thaliana , pollen normally develops three long and narrow, equally spaced apertures, but it remains unclear how pollen grains control the number and location of aperture domains. Zhou et al. found that mutations in two closely related A. thaliana proteins – ELMOD_A and MCR – alter the number and positions of pollen apertures. When A. thaliana plants were genetically modified so that they would produce different levels of ELMOD_A and MCR, Zhou et al. observed that when more of these proteins were present in a pollen grain, more apertures were generated on the pollen surface. This finding suggests that the levels of these proteins must be tightly regulated to control pollen aperture numbers. Further tests revealed that another related protein, called ELMOD_E, also has a role in domain formation. When artificially produced in developing pollen grains, it interfered with the activity of ELMOD_A and MCR, changing pollen aperture shape, number, and location. Zhou et al. identified a group of proteins that help control the formation of domains in the cell membranes of A. thaliana pollen grains. Further research will be required to determine what exactly these proteins do to promote formation of aperture domains and whether similar proteins control domain development in other organisms. 

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5. Reformulation of an extant ATPase active site to mimic ancestral GTPase activity reveals a nucleotide base requirement for function

   https://doi.org/10.7554/eLife.65845  

   Updegrove, Taylor B; Harke, Jailynn; Anantharaman, Vivek; Yang, Jin; Gopalan, Nikhil; Wu, Di; Piszczek, Grzegorz; Stevenson, David M; Amador-Noguez, Daniel; Wang, Jue D; et al (March 2021, eLife)

   null (Ed.)

   Living organisms need energy to stay alive; in cells, this energy is supplied in the form of a small molecule called adenosine triphosphate, or ATP, a nucleotide that stores energy in the bonds between its three phosphate groups. ATP is present in all living cells and is often referred to as the energy currency of the cell, because it can be easily stored and transported to where it is needed. However, it is unknown why cells rely so heavily on ATP when a highly similar nucleotide called guanosine triphosphate, or GTP, could also act as an energy currency. There are several examples of proteins that originally used GTP and have since evolved to use ATP, but it is not clear why this switch occurred. One suggestion is that ATP is the more readily available nucleotide in the cell. To test this hypothesis, Updegrove, Harke et al. studied a protein that helps bacteria transition into spores, which are hardier and can survive in extreme environments until conditions become favorable for bacteria to grow again. In modern bacteria, this protein uses ATP to provide energy, but it evolved from an ancestral protein that used GTP instead. First, Updegrove, Harke et al. engineered the protein so that it became more similar to the ancestral protein and used GTP instead of ATP. When this was done, the protein gained the ability to break down GTP and release energy from it, but it no longer performed its enzymatic function. This suggests that both the energy released and the source of that energy are important for a protein’s activity. Further analysis showed that the modern version of the protein has evolved to briefly hold on to ATP after releasing its energy, which did not happen with GTP in the modified protein. Updegrove, Harke et al. also discovered that the levels of GTP in a bacterial cell fall as it transforms into a spore, while ATP levels remain relatively high. This suggests that ATP may indeed have become the source of energy of choice because it was more available. These findings provide insights into how ATP became the energy currency in cells, and suggest that how ATP is bound by proteins can impact a protein’s activity. Additionally, these experiments could help inform the development of drugs targeting proteins that bind nucleotides: it may be essential to consider the entirety of the binding event, and not just the release of energy. 

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