Genetic determinants of serum testosterone concentrations in men

Testosterone concentrations in men are associated with cardiovascular morbidity, osteoporosis, and mortality and are affected by age, smoking, and obesity. Because of serum testosterone''s high heritability, we performed a meta-analysis of genome-wide association data in 8,938 men from seven cohorts and followed up the genome-wide significant findings in one in silico (n = 871) and two de novo replication cohorts (n = 4,620) to identify genetic loci significantly associated with serum testosterone concentration in men. All these loci were also associated with low serum testosterone concentration defined as <300 ng/dl. Two single-nucleotide polymorphisms at the sex hormone-binding globulin (SHBG) locus (17p13-p12) were identified as independently associated with serum testosterone concentration (rs12150660, p = 1.2×10⁻⁴¹ and rs6258, p = 2.3×10⁻²²). Subjects with ≥3 risk alleles of these variants had 6.5-fold higher risk of having low serum testosterone than subjects with no risk allele. The rs5934505 polymorphism near FAM9B on the X chromosome was also associated with testosterone concentrations (p = 5.6×10⁻¹⁶). The rs6258 polymorphism in exon 4 of SHBG affected SHBG''s affinity for binding testosterone and the measured free testosterone fraction (p<0.01). Genetic variants in the SHBG locus and on the X chromosome are associated with a substantial variation in testosterone concentrations and increased risk of low testosterone. rs6258 is the first reported SHBG polymorphism, which affects testosterone binding to SHBG and the free testosterone fraction and could therefore influence the calculation of free testosterone using law-of-mass-action equation.     

Lanthanide ion catalysis of the trans-cis isomerization of trans-bis(oxalato)-diaquochromate(III) and trans-bis(malonato)diaquochromate(III) [1]

The lanthanide ion catalyzed trans-cis isomerizations of trans-bis(oxalato)diaquochromate(II) and trans-bis(malonato)diaquochromate(III) have been studied. A linear free energy relationship was found correlating the catalytic rate constants for the oxalate reaction with the corresponding formation constants of complexes formed between simple monocarboxylic acids and the light (LaGd) members of the lanthanide series. The results indicates that for this portion of the series, the reaction mechanism is related to the formation of monocarboxylate complex intermediates. When the ionic radius of the lanthanide ion decreases below a particular value (as in the latter half of the series), the metal ion remains coordinated to both carboxylates of the oxalate ion rather than simply binding to only one carboxylate. In either situation, isomerization to the cis product eventually occurs, and the lanthanide ion is released.The reaction rates associated with the trans-bis(malonato)diaquochromate(III) reaction were found to be significantly slower than those of the corresponding oxalate system. However, in the malonate system, no linear free energy relationship was found relating the catalytic rate constants with the corresponding formation constants of monocarboxylic acids. One does find a linear relationship between the catalytic rate constants for the malonate reaction and the log K₁ values for the corresponding lanthanide/malonate complexes. During the course of the trans-cis isomerization, the lanthanide ion chelates the dissociated malonate group of a pentavalent Cr(III) intermediate. In the mechanism the lanthanide ion does not aid in ring opening, and neither does it singly bond to the intermediate     

Recognizing and defining true Ras binding domains I: biochemical analysis

Common domain databases contain sequence motifs which belong to the ubiquitin fold family and are called Ras binding (RB) and Ras association (RalGDS/AF6 Ras associating) (RA) domains. The name implies that they bind to Ras (or Ras-like) GTP-binding proteins, and a few of them have been documented to qualify as true Ras effectors, defined as binding only to the activated GTP-bound form of Ras. Here we have expressed a large number of these domains and investigated their interaction with Ras, Rap and M-Ras. While their (albeit weak) sequence homology suggest that the domains adopt a common fold, not all of them bind to Ras proteins, irrespective of whether they are called RB or RA domains. We used fluorescence spectroscopy and isothermal titration calorimetry to show that the binding affinities vary over a large range, and are usually specific for either Ras or Rap. Moreover, the specificity is dictated by a set of key residues in the interface. Stopped-flow kinetic analysis showed that the association rate constants determine the different affinities of effector binding, while the dissociation rate constants are in a similar range. Manual sequence analysis allowed us to define positively charged sequence epitopes in certain secondary structure elements of the ubiquitin fold (beta1, beta2 and alpha1) which are located at similar positions and comprise the hot spots of the binding interface. These residues are important to qualify an RA/RB domain as a true candidate Ras or Rap effector.     

SLAM family receptors distinguish hematopoietic stem and progenitor cells and reveal endothelial niches for stem cells

To improve our ability to identify hematopoietic stem cells (HSCs) and their localization in vivo, we compared the gene expression profiles of highly purified HSCs and non-self-renewing multipotent hematopoietic progenitors (MPPs). Cell surface receptors of the SLAM family, including CD150, CD244, and CD48, were differentially expressed among functionally distinct progenitors. HSCs were highly purified as CD150(+)CD244(-)CD48(-) cells while MPPs were CD244(+)CD150(-)CD48(-) and most restricted progenitors were CD48(+)CD244(+)CD150(-). The primitiveness of hematopoietic progenitors could thus be predicted based on the combination of SLAM family members they expressed. This is the first family of receptors whose combinatorial expression precisely distinguishes stem and progenitor cells. The ability to purify HSCs based on a simple combination of SLAM receptors allowed us to identify HSCs in tissue sections. Many HSCs were associated with sinusoidal endothelium in spleen and bone marrow, though some HSCs were associated with endosteum. HSCs thus occupy multiple niches, including sinusoidal endothelium in diverse tissues.     

Hansenula polymorpha Vam7p is required for macropexophagy

We have analyzed the functions of two vacuolar t-SNAREs, Vam3p and Vam7p, in peroxisome degradation in the methylotrophic yeast Hansenula polymorpha. A Hp-vam7 mutant was strongly affected in peroxisome degradation by selective macropexophagy as well as non-selective microautophagy. Deletion of Hp-Vam3p function had only a minor effect on peroxisome degradation processes. Both proteins were located at the vacuolar membrane, with Hp-Vam7p also having a partially cytosolic location. Previously, in baker's yeast Vam3p and Vam7p have been demonstrated to be components of a t-SNARE complex essential for vacuole biogenesis. We speculate that the function of this complex in macropexophagy includes a role in membrane fusion processes between the outer membrane layer of sequestered peroxisomes and the vacuolar membrane. Our data suggest that Hp-Vam3p may be functionally redundant in peroxisome degradation. Remarkably, deletion of Hp-VAM7 also significantly affected peroxisome biogenesis and resulted in organelles with multiple, membrane-enclosed compartments. These morphological defects became first visible in cells that were in the mid-exponential growth phase of cultivation on methanol, and were correlated with accumulation of electron-dense extensions that were connected to mitochondria.     

Ubiquitination of the peroxisomal targeting signal type 1 receptor, Pex5p, suggests the presence of a quality control mechanism during peroxisomal matrix protein import

PEX genes encode proteins (peroxins) that are required for the biogenesis of peroxisomes. One of these peroxins, Pex5p, is the receptor for matrix proteins with a type 1 peroxisomal targeting signal (PTS1), which shuttles newly synthesized proteins from the cytosol into the peroxisome matrix. We observed that in various Saccharomyces cerevisiae pex mutants disturbed in the early stages of PTS1 import, the steady-state levels of Pex5p are enhanced relative to wild type controls. Furthermore, we identified ubiquitinated forms of Pex5p in deletion mutants of those PEX genes that have been implicated in recycling of Pex5p from the peroxisomal membrane into the cytosol. Pex5p ubiquitination required the presence of the ubiquitin-conjugating enzyme Ubc4p and the peroxins that are required during early stages of PTS1 protein import. Finally, we provide evidence that the proteasome is involved in the turnover of Pex5p in wild type yeast cells, a process that requires Ubc4p and occurs at the peroxisomal membrane. Our data suggest that during receptor recycling a portion of Pex5p becomes ubiquitinated and degraded by the proteasome. We propose that this process represents a conserved quality control mechanism in peroxisome biogenesis.     

Atg21p is essential for macropexophagy and microautophagy in the yeast Hansenula polymorpha

ATG genes are required for autophagy-related processes that transport proteins/organelles destined for proteolytic degradation to the vacuole. Here, we describe the identification and characterisation of the Hansenula polymorpha ATG21 gene. Its gene product Hp-Atg21p, fused to eGFP, had a dual location in the cytosol and in peri-vacuolar dots. We demonstrate that Hp-Atg21p is essential for two separate modes of peroxisome degradation, namely glucose-induced macropexophagy and nitrogen limitation-induced microautophagy. In atg21 cells subjected to macropexophagy conditions, sequestration of peroxisomes tagged for degradation is initiated but fails to complete.     

Crystallographic Insights into the Pore Structures and Mechanisms of the EutL and EutM Shell Proteins of the Ethanolamine-Utilizing Microcompartment of Escherichia coli

The ethanolamine-utilizing bacterial microcompartment (Eut-BMC) of Escherichia coli is a polyhedral organelle that harbors specific enzymes for the catabolic degradation of ethanolamine. The compartment is composed of a proteinaceous shell structure that maintains a highly specialized environment for the biochemical reactions inside. Recent structural investigations have revealed hexagonal assemblies of shell proteins that form a tightly packed two-dimensional lattice that is likely to function as a selectively permeable protein membrane, wherein small channels are thought to permit controlled exchange of specific solutes. Here, we show with two nonisomorphous crystal structures that EutM also forms a two-dimensional protein membrane. As its architecture is highly similar to the membrane structure of EutL, it is likely that the structure represents a physiologically relevant form. Thus far, of all Eut proteins, only EutM and EutL have been shown to form such proteinaceous membranes. Despite their similar architectures, however, both proteins exhibit dramatically different pore structures. In contrast to EutL, the pore of EutM appears to be positively charged, indicating specificity for different solutes. Furthermore, we also show that the central pore structure of the EutL shell protein can be triggered to open specifically upon exposure to zinc ions, suggesting a specific gating mechanism.Bacterial microcompartments are subcellular organelles that are found in many prokaryotic organisms (10, 32). In contrast to the lipidic vesicles of many eukaryotic cells, these enclosures are entirely composed of proteins. Recent imaging by electron microscopy revealed capsid-like particles obeying 2-, 3- and 5-fold symmetries that suggest icosahedral symmetry (4, 13, 27). Shell proteins are thought to form a tightly sealed membrane structure that separates the lumen from the cytosol. Similar to the lipidic membranes of vesicles, these proteinaceous membranes have been suggested to provide a selectively permeable solute barrier, wherein specific pores maintain an optimal biochemical environment for the catabolic reactions inside (25).The ethanolamine-utilizing bacterial microcompartment (Eut-BMC) enables some bacteria to survive on ethanolamine as the sole source for carbon, nitrogen, and energy (25). It is encoded by a 17-gene-containing operon, and homologues of its genes have been identified in Escherichia coli, Salmonella enterica serovar Typhimurium, Mycobacterium tuberculosis, and Clostridium kluyveri among other prokaryotic pathogens (22). Largely based on sequence comparisons, the compartment''s outer shell was proposed to be composed of five different shell proteins: Eut-K, -L, -M, -N, and -S, all of which are fairly small proteins that typically consist of about 100 amino acids. Only EutL is about twice the size, with 216 amino acids as a result of two tandemly duplicated shell protein domains (26).To date, little is known about the composition, architecture, and function of bacterial microcompartments. Recent structural investigations of BMC particles and individual shell proteins, however, have contributed greatly to a basic understanding of BMC architecture. Electron microscopy, for example, has revealed polyhedral shell structures that are composed of a thin layer of proteins. Intriguingly, crystallizations revealed that some shell proteins also assemble into tightly packed two-dimensional arrays that may resemble the facets of the compartments (28). Within an array, these proteins typically assembled into hexamers or trimers (in the case of tandem domain proteins) that exhibited a distinct hexagonal shape. As this geometry was suggested to be of fundamental importance to the microcompartment architecture, we will here refer to it as a “tile” or “tile structure.” While it has not yet been proven directly that the assembly of proteins in the crystals is identical to that of the BMC, their almost seamless two-dimensional packing has been suggested to be of physiological relevance as it could provide an efficient barrier to prevent leakage of toxic by-products into the cytoplasm (4, 25). Overall, however, it is not understood how the various shell proteins assemble to form the polyhedral structure while maintaining an efficiently tight seal. In particular, the interactions among the shell proteins and their arrangements within facets, edges, and vertices have remained elusive.In the study presented here, we demonstrate for the first time that the shell protein EutM is also able to form tightly packed two-dimensional arrays. With two independently determined crystal structures, we show that its protein array closely resembled that of EutL and other carboxysomal proteins. As a result, we hypothesize that this assembly represents a physiologically relevant form. Both crystal forms also revealed the C-terminal tail of the protein, which is proposed to serve as a potential interaction site with other factors.Furthermore, we show that the pore structure of EutL can be triggered to open upon exposure to specific solutes. A first structure of EutL was previously determined in our laboratory, and it revealed three water-filled pores per tile (26). Interestingly, its structure consisted of two tandemly repeated shell protein domains, which assembled into an almost perfectly shaped hexagonal structure. This architectural feature was recently also found in shell proteins of other microcompartments (11, 20). Each of the pores of an EutL tile was coated with acidic residues, which indicated a possible pathway for positively charged molecules such as ethanolamine. Inspection of the structure also suggested specific metal binding sites on its surface. In order to verify this idea, we performed systematic soaking studies of the crystals with selected divalent metals. Surprisingly, we found that zinc ions bound to the protein specifically not at the suspected sites but at different sites that caused a dramatic opening of a central pore. This unprecedented observation of a specifically triggered pore opening is consistent with another previous observation (30) and may point to a mechanism for regulation of permeability.     

Molecular localization of a ribosome-dependent ATPase on Escherichia coli ribosomes

We have previously isolated and described an Escherichia coli ribosome-bound ATPase, RbbA, that is required for protein synthesis in the presence of ATP, GTP and the elongation factors, EF-Tu and EF-G. The gene encoding RbbA, yhih, has been cloned and the deduced protein sequence harbors two ATP-motifs and one RNA-binding motif and is homologous to the fungal EF-3. Here, we describe the isolation and assay of a truncated form of the RbbA protein that is stable to overproduction and purification. Chemical protection results show that the truncated RbbA specifically protects nucleotide A937 on the 30S subunit of ribosomes, and the protected site occurs at the E-site where the tRNA is ejected upon A-site occupation. Other weakly protected bases in the region occur at or near the mRNA binding site. Using radiolabeled tRNAs, we study the stimulating effect of this truncated RbbA on the binding and release of different tRNAs bound to the (aminoacyl) A-, (peptidyl) P- and (exit) E-sites of 70S ribosomes. The combined data suggest plausible mechanisms for the function of RbbA in translation.     

Shaping dots and lines: adding modularity into protein interaction networks using structural information

Determining protein interaction networks and generating models to simulate network changes in time and space are crucial for understanding a biological system and for predicting the effect of mutants found in diseases. In this review we discuss the great potential of using structural information together with computational tools towards reaching this goal: the prediction of new protein interactions, the estimation of affinities and kinetic rate constants between protein complexes, and finally the determination of which interactions are compatible with each other and which interactions are exclusive. The latter one will be important to reorganize large scale networks into functional modular networks.