Changes in hydrolytic enzyme activities in armadillos infected with Mycobacterium leprae

The activities of hydrolytic enzymes in various organs of armadillos infected with Mycobacterium leprae were compared with those in normal armadillos. Except for aspartate aminopeptidase and esterase, the levels of the other enzymes in liver, spleen and inguinal lymph nodes were significantly higher in armadillos infected with M. leprae compared with those in non-infected ones. These enzymes levels were at a maximum when the animals were sacrificed 22 to 30 months post-inoculation, a period when the bacterial load in the animals had also reached a maximum. Animals infected with M. leprae but not showing any signs of disseminated infection behaved similar to those in the non-infected group. The observed changes in enzymatic activities were not due to bacterial enzymes and so can be related to tissue damage caused by M. leprae.     

ATP content of Mycobacterium tuberculosis grown in vivo and in vitro

In order to determine the reason for the slow growth of Mycobacterium leprae either in a host or in vitro, the growth characteristics of Mycobacterium tuberculosis were studied. The ATP content of in vitro-grown M. tuberculosis was about 520 pg/10(6) viable organisms. The ATP levels from in vivo-derived organisms obtained from liver and spleen of mice was about 130 pg (in cases of chronic infection) and about 270 pg (in cases of acute infection). When the in vivo-derived organisms were inoculated into culture medium, the growth rates for both types of organisms, acute as well as chronic infection, were the same and the maximum growth was reached during the fifth subculture. Although the maximum ATP content for both types of organism was the same, it was attained during the 4th subculture for organisms obtained during acute infection and during the 6th subculture for those obtained during chronic infection. The comparison between the ATP content of M. leprae and of M. tuberculosis indicates the reason for the slow growth of M. leprae.     

Conformation and activity of delta-lysin and its analogs

Delta-Lysin is a 26-residue hemolytic peptide secreted by Staphylococcus aureus. Unlike the bee venom peptide melittin, delta-lysin does not exhibit antibacterial activity. We have synthesized delta-lysin and several analogs wherein the N-terminal residues of the toxin were sequentially deleted. The toxin has three aspartic acids, four lysines and no prolines. Analogs were also generated in which all the aspartic acids were replaced with lysines. A proline residue was introduced in the native sequences as well as in the analogs where aspartic acids were replaced with lysines. We observed that 20- and 22-residue peptides corresponding to residues 7-26 and 5-26 of delta-lysin, respectively, had greater hemolytic activity than the parent peptide. These shorter peptides, unlike delta-lysin, did not self-associate to adopt alpha-helical conformation in water, at lytic concentrations. Introduction of proline or substitution of aspartic acids by lysines resulted in loss in propensity to adopt helical conformation in water. When proline was introduced in the peptides corresponding to the native toxin sequence, loss of hemolytic activity was observed. Substitution of all the aspartic acids with lysines resulted in enhanced hemolytic activity in all the analogs. However, when both proline and aspartic acid to lysine changes were made, only antibacterial activity was observed in the shorter peptides. Our investigations on delta-lysin and its analogs provide insights into the positioning of anionic, cationic residues and proline in determining hemolytic and antibacterial activities.     

The human beta-defensin-3, an antibacterial peptide with multiple biological functions

A group of interesting molecules called defensins exhibit multiple functions but have been primarily recognized to possess a broad spectrum of antimicrobial activities. Studies have reported two different types of defensins (α and β) from human and animals, a cyclic θ defensin from rhesus, and several defensin-like peptides from plants. There is no amino acid sequence homology between these peptides, but they all contain three Cys-Cys disulfide linkages while the connectivities are different. Human β-defensin-3 (HβD-3) is the most recently discovered member of the host-defense peptide family that has attracted much attention. This molecule is expressed either constitutively or induced upon a challenge, and a growing evidence indicates the involvement of such molecules in adaptive immunity as well. It has been shown to exhibit antibacterial activities towards Gram-negative and Gram-positive bacteria as well as an ability to act as a chemo-attractant. Analysis of NMR structural data suggested a symmetrical dimeric form of this peptide in solution, which consists of three β strands and a short helix in the N-terminal region. While the disulfide linkages are known to provide the structural stability and stability against proteases, the biological relevance of this dimeric form was contradicted by another biological study. Since there is considerable current interest in developing HβD-3 for possible pharmaceutical applications, studies to further our understanding on the determinants of antibacterial activities and immunomodulatory function of HβD-3 are considered to be highly significant. The knowledge of its biosynthetic regulation will also help in understanding the role of HβD-3 in immunity. This article presents an overview of the expression and regulation of HβD-3 in humans, and the structure-function correlations among HβD-3 and its modified peptides are discussed emphasizing the functional importance. The future scope for studies on HβD-3 and design of short potent antimicrobial peptides, based on the native HβD-3 molecule, that do not interfere in the immunomodulatory function is also outlined.     

Protein-protein-interaction Network Organization of the Hypusine Modification System

Hypusine modification of eukaryotic initiation factor 5A (eIF-5A) represents a unique and highly specific post-translational modification with regulatory functions in cancer, diabetes, and infectious diseases. However, the specific cellular pathways that are influenced by the hypusine modification remain largely unknown. To globally characterize eIF-5A and hypusine-dependent pathways, we used an approach that combines large-scale bioreactor cell culture with tandem affinity purification and mass spectrometry: “bioreactor-TAP-MS/MS.” By applying this approach systematically to all four components of the hypusine modification system (eIF-5A1, eIF-5A2, DHS, and DOHH), we identified 248 interacting proteins as components of the cellular hypusine network, with diverse functions including regulation of translation, mRNA processing, DNA replication, and cell cycle regulation. Network analysis of this data set enabled us to provide a comprehensive overview of the protein-protein interaction landscape of the hypusine modification system. In addition, we validated the interaction of eIF-5A with some of the newly identified associated proteins in more detail. Our analysis has revealed numerous novel interactions, and thus provides a valuable resource for understanding how this crucial homeostatic signaling pathway affects different cellular functions.Cellular homeostasis is controlled by signaling networks that communicate through post-translational modifications (PTM)¹ of proteins, including phosphorylation, acetylation and methylation (1–3). These modifications are typically attached to various types of proteins by multiple independent enzymes, and thereby simultaneously regulate a wide range of protein functions. Consequently, most signaling pathways are highly redundant, enabling maintenance of cellular integrity even if the modification of a single signaling molecule is disrupted (4). A striking exception is hypusine. This essential PTM is limited to a single protein: the eukaryotic initiation factor 5A (eIF-5A) (5). Disruption of this PTM leads to growth arrest in proliferating eukaryotic cells and is fatal for the developing mammalian embryo (6, 7). During hypusine biosynthesis, the lysine residue at position 50 (Lys₅₀) in eIF-5A is converted into the unusual amino acid hypusine (N^ε-(4-amino-2-hydroxybutyl)lysine; depicted in Fig. 1A) (5). This process activates eIF-5A and is mediated by two enzymatic reactions: first, deoxyhypusine synthase (DHS) catalyzes the transfer of the 4-aminobutyl moiety of spermidine to the ε-amino group of Lys₅₀ to form an intermediate residue, deoxyhypusine (Dhp₅₀) (8). Subsequently, deoxyhypusine hydroxylase (DOHH) mediates the formation of hypusine (Hyp₅₀) by addition of a hydroxyl group to the deoxyhypusine residue (9). eIF-5A, DHS and DOHH are all essential for proliferation of higher eukaryotic cells (10, 11), and eIF-5A is strictly conserved throughout eukaryotic evolution (12).Open in a separate windowFig. 1.The hypusine modification and TAP fusion proteins employed in this study. A, The hypusine modification pathway and major proposed eIF-5A functions. B, Structure of the plasmid inserts coding for SG-tagged bait proteins. The amino acid positions of eIF-5A mutants are indicated in italic. SBP, streptavidin binding peptide. C, Metabolic incorporation of ³H-labeled spermidine into eIF-5A. Arrowheads indicate bands of SG-tagged and endogenous eIF-5A proteins. D, Anti-Myc-tag Western blot of cell lysates from retrovirally transduced Ba/F3 p210 cell lines for the quantification of constitutively expressed SG-tagged bait proteins. E, Representative TAP outputs for MS/MS analysis, after 1D PAGE separation and Coomassie staining. Separation distance varies from ∼2 to 4 cm.The eIF-5A protein has been proposed to promote various different cellular processes that potentially regulate proliferation, including translation initiation (13) and elongation (14) as well as nucleocytoplasmic transport of RNA or other cargoes (15, 16). Using inhibitors of DHS and DOHH or eIF-5A mutants deficient for hypusine modification, it has also been shown that this modification is a prerequisite of at least a subset of known eIF-5A functions (10, 11, 17, 18). The eIF-5A protein has also been implicated in numerous pathologic conditions including various types of cancer (19–23), β-cell inflammation (and therefore diabetes) (24) and HIV-1 infection (25). Human and rodent cells carry two highly homologous eIF-5A genes coding for distinct isoforms. Although eIF-5A1 is expressed at high levels throughout all tissues, eIF-5A2 is detectable only in a few embryonic tissues as well as adult testis, central nervous system (26), and cancer tissue (21, 22, 27–29).Although there have been ample reports suggesting eIF-5A is involved in translational control, the molecular mechanisms through which it ultimately influences cellular physiology and leads to disease remain unclear. Moreover, it remains equally possible that at least some of eIF-5A''s effects on cellular functions might not involve direct effects on translation. Also, there is no information available on whether the two isoforms of mammalian eIF-5A are functionally congruent.To address these fundamental questions systematically and comprehensively, we employed a bioreactor-based tandem affinity purification (TAP) approach followed by MS identification of purified protein complexes (“bioreactor-TAP-MS/MS”). To obtain a complete interaction map of the proteins involved in hypusine modification, we used this approach to identify interaction partners of both isoforms of eIF-5A, as well as the hypusine modification enzymes DHS and DOHH. In total, we identified 248 proteins that either directly interact with these bait proteins or are components of higher complexes containing the aforementioned proteins. Furthermore, we validated a subset of putative interaction partners of both eIF-5A isoforms, using Western blots of reciprocal TAP experiments, as well as a live-cell protein-fragment complementation assay (PCA). Our analysis provides a molecular framework for a detailed understanding on how this signal transduction pathway affects different crucial cellular functions.     

Quantitative Extraction of Adenosine Triphosphate from Cultivable and Host-Grown Microbes: Calculation of Adenosine Triphosphate Pools

Existing data on adenosine triphosphate (ATP) pools in microbes are deficient for two reasons: (i) incomplete extractions of ATP, and (ii) the failure to take into account that the adverse effects of extracting procedures on standard ATP exert analogous effects on the ATP released from bacterial cells. Methods for correcting observed yields and calculating ATP pools have been demonstrated. Three bacterial species were used in the studies on extraction of ATP: Escherichia coli, Mycobacterium phlei, and Mycobacterium lepraemurium. Perchloric acid and n-butanol were disqualified because of their failure to extract total bacterial ATP even from E. coli and because of inconvenient procedures. The new extraction procedure had minimal effects on standard ATP, liberated 100% of the ATP pools from the three representative species of microbes, and caused no ionic imbalance or quenching of bioluminescence. This method involves vortexing of cell suspensions for 10 s with 23% chloroform (vol/vol), heating at 98 C for the required time (E. coli, 3 min; M. phlei, 5 min; M. lepraemurium, 10 min) and then 1 min at 98 C with vacuum to dry the samples. Heat or chloroform alone may suffice for some microbes and release total ATP from plant and animal cells.     

Gene structure,transcripts and calciotropic effects of the PTH family of peptides in <Emphasis Type="Italic">Xenopus</Emphasis> and chicken

Background  

Parathyroid hormone (PTH) and PTH-related peptide (PTHrP) belong to a family of endocrine factors that share a highly conserved N-terminal region (amino acids 1-34) and play key roles in calcium homeostasis, bone formation and skeletal development. Recently, PTH-like peptide (PTH-L) was identified in teleost fish raising questions about the evolution of these proteins. Although PTH and PTHrP have been intensively studied in mammals their function in other vertebrates is poorly documented. Amphibians and birds occupy unique phylogenetic positions, the former at the transition of aquatic to terrestrial life and the latter at the transition to homeothermy. Moreover, both organisms have characteristics indicative of a complex system in calcium regulation. This study investigated PTH family evolution in vertebrates with special emphasis on Xenopus and chicken.     

Tyrosine phosphoproteome of hamster spermatozoa: Role of glycerol‐3‐phosphate dehydrogenase 2 in sperm capacitation

Capacitation confers on the spermatozoa the competence to fertilize the oocyte. At the molecular level, a cyclic adenosine monophosphate (cAMP) dependent protein tyrosine phosphorylation pathway operates in capacitated spermatozoa, thus resulting in tyrosine phosphorylation of specific proteins. Identification of these tyrosine‐phosphorylated proteins and their function with respect to hyperactivation and acrosome reaction, would unravel the molecular basis of capacitation. With this in view, 21 phosphotyrosine proteins have been identified in capacitated hamster spermatozoa out of which 11 did not identify with any known sperm protein. So, in the present study attempts have been made to ascertain the role of one of these eleven proteins namely glycerol‐3‐phosphate dehydrogenase 2 (GPD2) in hamster sperm capacitation. GPD2 is phosphorylated only in capacitated hamster spermatozoa and is noncanonically localized in the acrosome and principal piece in human, mouse, rat, and hamster spermatozoa, though in somatic cells it is localized in the mitochondria. This noncanonical localization may imply a role of GPD2 in acrosome reaction and hyperactivation. Further, enzymatic activity of GPD2 during capacitation correlates positively with hyperactivation and acrosome reaction thus demonstrating that GPD2 may be required for sperm capacitation.