MicroID2: A Novel Biotin Ligase Enables Rapid Proximity-Dependent Proteomics

Identifying protein–protein and other proximal interactions is central to dissecting signaling and regulatory processes in cells. BioID is a proximity-dependent biotinylation method that uses an “abortive” biotin ligase to detect proximal interactions in cells in a highly reproducible manner. Recent advancements in proximity-dependent biotinylation tools have improved efficiency and timing of labeling, allowing for measurement of interactions on a cellular timescale. However, issues of size, stability, and background labeling of these constructs persist. Here we modified the structure of BioID2, derived from Aquifex aeolicus BirA, to create a smaller, highly active, biotin ligase that we named MicroID2. Truncation of the C terrminus of BioID2 and addition of mutations to alleviate blockage of biotin/ATP binding at the active site of BioID2 resulted in a smaller and highly active construct with lower background labeling. Several additional point mutations improved the function of our modified MicroID2 construct compared with BioID2 and other biotin ligases, including TurboID and miniTurbo. MicroID2 is the smallest biotin ligase reported so far (180 amino acids [AAs] for MicroID2 versus 257 AAs for miniTurbo and 338 AAs for TurboID), yet it demonstrates only slightly less labeling activity than TurboID and outperforms miniTurbo. MicroID2 also had lower background labeling than TurboID. For experiments where precise temporal control of labeling is essential, we in addition developed a MicroID2 mutant, termed lbMicroID2 (low background MicroID2), that has lower labeling efficiency but significantly reduced biotin scavenging compared with BioID2. Finally, we demonstrate utility of MicroID2 in mass spectrometry experiments by localizing MicroID2 constructs to subcellular organelles and measuring proximal interactions.     

Evidence Against Impaired Brain Microtubule Protein Polymerization at High Glucose Concentrations or During Diabetes Mellitus

Previous studies suggest that brain microtubule protein exposed to high glucose levels or isolated from diabetic rats can become glucosylated and that this impairs GTP-induced microtubule polymerization. We set out to extend that investigation to define the mechanistic basis for inhibition of microtubule assembly during diabetes or on incubation at high glucose levels. Rat and bovine brain microtubule protein was purified by cycles of polymerization/depolymerization. When microtubules were incubated for 1 h in either buffer or buffer containing glucose (up to 165 mM), there was no difference in polymerization, a finding contrary to the earlier study. Other rats were injected with vehicle or streptozotocin (90 mg/kg) to induce diabetes as evidenced by serum glucose in excess of 300 mg%, and at 4 weeks, brain microtubule protein was isolated by the polymerization cycling method. Again, there was no difference in the amount or purity of isolated microtubule protein between control or diabetic rats. We also observed no increase in microtubule glucosylation, and GTP-induced polymerization in vitro was indistinguishable for protein derived from brains of normal rats and rats with diabetes as measured by turbidity or electron microscopy. Our results suggest that in vitro incubation with glucose or in vivo elevation of glucose during diabetes fails to impair microtubule polymerization, pointing to other mechanisms for the neuropathy associated with diabetes.     

Conditional lethality involving a cytoplasmic mutant and chlorophyll-deficient malate dehydrogenase mutants in soybean

Summary Conditional lethality in soybean, Glycine max (L.) Merr., occurred in F₂ plants when cytoplasmicchlorophyll mutant Genetic Type T275 was the female parent and when either nuclear mutants T253 or T323 plants were the male parents. Mutant T253 [Mdh1-n (Urbana) y20 (Urbana) k2] is missing two of three mitochondrial malate dehydrogenase isozymes [Mdh1-n (Urbana)] and has yellowish-green leaves [y20 (Urbana)] and a tan-saddle pattern seed coat (k2). Mutant T323 [Mdh1-n (Ames 2) y20 (Ames 2)] also is missing two of three mitochondrial malate dehydrogenase isozymes [Mdh1-n (Ames 2)] and has yellowishgreen leaves [y20 (Ames 2)], but has yellow seed coat (K2). Mutants T275, T253, and T323 are viable both in the field and glasshouse. The genotypes cyt-Y2 Mdh1-n (Urbana) y20 (Urbana) k2/Mdh1-n (Urbana) y20 (Urbana) k2 and cyt-Y2 Mdh1-n (Ames 2) y20 (Ames 2)/Mdh1-n (Ames 2) y20 (Ames 2) are conditional lethals. These genotypes are lethal under field conditions, but plants survive in reduced light under shadecloth in the glasshouse. We do not know if their interaction with cyt-Y2 is due to Mdh1-n, y20, or Mdh1-n y20. The reciprocal cross (cyt-Y2 as male parent) gives viable genotypes. These conditional lethal genotypes should be useful for studies on the interaction between organelle and nuclear genomes.This is journal paper no. J-14777 of the Iowa Agriculture and Home Economics Experiment Station, Ames, IA 50011-1010. Project 2985     

The Oil Bodies of Liverworts: Unique and Important Organelles in Land Plants

Oil bodies of liverworts are intracellular organelles bounded by a single unit membrane containing lipophilic globules suspended in a proteinaceous matrix. They are a prominent and highly distinctive organelle uniquely found in liverworts. Although they have been widely used in taxonomy and chemosystematics, and many of their secondary metabolites are known to be bioactive and are considered as potential sources of medicines, their origin, development and function still remain poorly understood. Recently, biochemical studies have indicated that the isoprenoid biosynthetic pathways in liverworts are similar to those of the seed plants and that oil bodies of Marchantia polymorpha contain a protein complex immunologically related to plastid and cytosolic enzymes of isoprenoid synthesis. Cytoplasmic lipid droplets lacking a bounding membrane have recently been recognized as important dynamic organelles playing active roles in cell physiology. Structural proteins, covering the surface of the lipid droplets and preventing them coalescing during desiccation, have been found in seed plants and also in the moss Physcomitrella patens. However, whether liverwort oil bodies play a dynamic role in cell metabolism, in addition to their role as sites of essential oil accumulation and sequestration, has not been formally tested. In this review, we present current knowledge on the oil bodies of liverworts on their origin and development, their role in taxonomy, chemosystematics and potential pharmaceutical applications leading to their functional significance, and we also identify avenues for future studies on this important but long-overlooked organelle.     

Genetic and evolutionary consequences of symbiosis

Permanent stable symbioses, primarily microbial, are analyzed as parasexual phenomena from the evolutionary point of view. Such associations bring together in single individuals heritable traits of high selective advantage in certain environments. By convergent evolution several types of associations have repeatedly arisen: motile photosynthetic forms, nitrogen fixing and wood digesting complexes, and so forth. Many examples are discussed from the point of view of the number of originally independent genomes that comprise the recognizable individuals.The level of partner integration in many associations is analyzed. Examples of many levels: genic, gene product, metabolite, behavioral, and the methods by which they can be distinguished are discussed.The literature concerning a large number of associations is reviewed: Methanobacillus; predatory and consortia bacteria; blue green algal sheath dwelling bacteria; anaerobic worm-bacterial; algal, and foreign chloroplast retention by heterotrophic eukaryotes (ciliates, coelenterates, mollusks); the double nucleated photosynthetic dinoflagellate (Peridinium balticum); hindgut microbes in termites and woodroaches (Pyrsonympha, Barbulanympha and their associated spirochetes and other bacteria); sand dwelling and other ciliates and their associated bacteria; and so forth. The status of observations and artificial systems claiming evidence for transfer of genes between very distantly related organisms is critically discussed.A continuum from nearly completely autonomous partners (e.g., zoochlorellae in invertebrate animals) to nearly unrecognizable merged components (e.g., gamma particles in Blastocladiella) is found to exist among examples of extant organisms. The diversity and prevalence of such associations support the concept that there are many precedents for the steps hypothesized in the serial endosymbiotic theory of the origin of eukaryotic cells.     

Determinants of the assembly,integrity and maintenance of the endoplasmic reticulum‐peroxisome tether

Organelle tethering and intercommunication are crucial for proper cell function. We previously described a tether between peroxisomes and the endoplasmic reticulum (ER) that acts in peroxisome population control in the yeast, Saccharomyces cerevisiae. Components of this tether are Pex3p, an integral membrane protein of both peroxisomes and the ER and Inp1p, a connector that links peroxisomes to the ER. Here, we report the analysis of random Inp1p mutants that enabled identification of regions in Inp1p required for the assembly and maintenance of the ER‐peroxisome tether. Interaction analysis between Inp1p mutants and known Inp1p‐binding proteins demonstrated that Pex3p and Inp1p do not constitute the sole components of the ER‐peroxisome tether. Deletion of these Inp1p interactors whose steady‐state localization is outside of ER‐peroxisome tethers affected peroxisome dynamics. Our findings are consistent with the presence of regulatory cues that act on ER‐peroxisome tethers and point to the existence of membrane contact sites between peroxisomes and organelles other than the ER.      

SubCellBarCode: Proteome-wide Mapping of Protein Localization and Relocalization

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Condensed,Microtubule-coating Thin Organelles for Orthogonal Translation in Mammalian Cells

Membraneless organelles are capable of selectively performing complex tasks in living cells despite dynamically exchanging with their surroundings. This is an exquisite example how self-organization of proteins and RNAs can lead to more complex functionalities in living systems. Importantly, the absence of a membrane boundary can enable easier access to larger macromolecular complexes that can be challenging to be transported across a membrane. We previously formed orthogonally translating designer membraneless organelles by combining phase separation with kinesin motor proteins to highly enrich engineered translational factors in large organelles. We also showed that even submicron thick designer organelles can be formed, by mounting them onto membranes, which, presumable assisted by 2D condensation, leads to thin film-like condensates. In this study we show that orthogonal translation can also be built with fiber-like appearing organelles. Here, the microtubule-end binding protein EB1 was used to form fiber-like OT organelles along the microtubule cytoskeleton that perform highly selective and efficient orthogonal translation. We also show an improved simplified design of OT organelles. Together this extends OT organelle technology and demonstrates that the microtubule cytoskeleton is a powerful platform for advanced synthetic organelle engineering.