Nitric oxide regulation of cGMP production in osteoclasts

Bone resorption by osteoclasts is modified by agents that affect cyclic guanosine monophosphate (cGMP), but their relative physiological roles, and what components of the process are present in osteoclasts or require accessory cells such as osteoblasts, are unclear. We studied cGMP regulation in avian osteoclasts, and in particular the roles of nitric oxide and natriuretic peptides, to clarify the mechanisms involved. C-type natriuretic peptide drives a membrane guanylate cyclase, and increased cGMP production in mixed bone cells. However, C-type natriuretic peptide did not increase cGMP in purified osteoclasts. By contrast, osteoclasts did produce cGMP in response to nitric oxide (NO) generators, sodium nitroprusside or 1-hydroxy-2-oxo-3,3-bis(3-aminoethyl)-1-triazene. These findings indicate that C-type natriuretic peptide and NO modulate cGMP in different types of bone cells. The activity of the osteoclast centers on HCI secretion that dissolves bone mineral, and both NO generators and hydrolysis-resistant cGMP analogues reduced bone degradation, while cGMP antagonists increased activity. NO synthase agonists did not affect activity, arguing against autocrine NO production. Osteoclasts express NO-activated guanylate cyclase and cGMP-dependent protein kinase (G-kinase). G-kinase reduced membrane HCI transport activity in a concentration-dependent manner, and phosphorylated a 60-kD osteoclast membrane protein, which immunoprecipitation showed is not an H+-ATPase subunit. We conclude that cGMP is a negative regulator of osteoclast activity. cGMP is produced in response to NO made by other cells, but not in response to C-type natriuretic peptide. G-kinase modulates osteoclast membrane HCI transport via intermediate protein(s) and may mediate cGMP effects in osteoclasts.     

Detection of chromosome aberrations by FISH as a function of cell division cycle (harlequin-FISH)

Chromosome aberrations are a sensitive indicator of genetic change, and the measurement of chromosome aberration frequency in peripheral blood lymphocytes is often used as a biological dosimeter of exposure (1,4). The length of time that cells are maintained in culture before cytogenetic analysis is probably the most important in vitro factor that influences both the frequency and types of aberrations that are seen following exposure to mutagens. Therefore, for accurate cytogenetic measurements of genetic damage, cells must be analyzed in their first mitosis following exposure. As cells progress through subsequent mitotic division cycles, cells with unstable types of aberrations, e.g., dicentrics and acentric fragments, are eliminated (1,3,4). Even the use of synchronized populations of cells does not guarantee that all cells analyzed will be in their first division following treatment. Small variations in growth rate after irradiation can lead to large variations in the proportion of cells that are in their first vs. a subsequent mitosis. For example, 48 h after G0 lymphocytes are stimulated to enter the cell cycle (the standard sampling time for cytogenetic analysis), up to 50% of the cells in mitosis can be in their second division cycle (10). While there are methods available to distinguish cells in different division cycles (see Introduction), they are not easily adapted for use with standard fluorescence in situ hybridization (FISH) procedures. The goal of this study was to develop a simple approach to detect aberrations by FISH whereby cells in different division cycles could be distinguished.     

S-protein mutants indicate a functional role for SBP in the self-incompatibility reaction of Papaver rhoeas

The self-incompatibility response involves S-allele specific recognition between stigmatic S proteins and incompatible pollen, resulting in S-specific pollen inhibition. In Papaver rhoeas, the pollen S gene product is predicted to be a receptor that interacts with the stigmatic S protein in an S specific manner. We recently identified an S protein binding protein (SBP) in pollen that binds stigmatic S proteins, although apparently not in an S-allele-specific manner. In order to investigate the functional significance of the interaction between S proteins and SBP, we constructed mutant derivatives of the S1 protein and tested their SBP-binding activity and their biological activity. Here we present an evaluation of nine mutant derivatives of the S1 protein. Western ligand blotting was used to show that mutations to amino acid residues in predicted loops 2 and 6 of the S1 protein cause significant reductions in their SBP-binding activity. These same mutants show a concomitant reduction in their ability to inhibit incompatible pollen. This establishes a direct link between SBP binding and inhibition of incompatible pollen and implicates SBP as a pollen component playing a key role in the self-incompatibility reaction. We discuss the possible nature of the contribution of SBP in the S-specific rejection of incompatible pollen.     

Reversible and irreversible hemichrome generation by the oxygenation of nitrosylmyoglobin

The repeated oxygenation/reduction/nitrosylation of nitrosylmyoglobin produces low-spin ferric heme hemichromes which have been characterized by electron spin resonance spectroscopy. The predominant myoglobin hemichrome is a chemically reversible dihistidyl complex identified by the g values 1.53, 2.21, and 2.97. Also present is a low-spin ferric hydroxide derivative which is represented by the g values 1.83, 2.18, and 2.59. The formation of these species goes undetected by UV-vis spectroscopy, but the oxygenation of myoglobin to metmyoglobin is correlated with complete conversion of nitric oxide to nitrate which is released following a clear induction period. These results are interpreted in terms of the intermediates generated during the MbNO oxygenation reaction.     

European guidelines for quality assurance in cervical cancer screening: recommendations for collecting samples for conventional and liquid-based cytology.

The current paper presents an annex in the second edition of the European Guidelines for Quality Assurance in Cervical Cancer Screening. It provides guidance on how to make a satisfactory conventional Pap smear or a liquid-based cytology (LBC) sample. Practitioners taking samples for cytology should first explain to the woman the purpose, the procedure and how the result will be communicated. Three sampling methods are considered as acceptable for preparing conventional Pap smears: (i) the cervical broom; (ii) the combination of a spatula and an endocervical brush; and (iii) the extended tip spatula. Smear takers should take care to sample the entire circumference of the transformation zone, to quickly spread the cellular material over a glass slide, and to fix the preparation within a few seconds to avoid drying artefacts. According to local guidelines, one of these three methods may be preferred. Sampling with a cotton tip applicator is inappropriate. Similar procedures should be followed for sampling cells for LBC, but only plastic devices may be used. The collected cells should be quickly transferred into a vial with fixative liquid according to the instructions of the manufacturer of the LBC system. Subsequently, the slide or vial and the completed request form are sent to the laboratory for cytological interpretation.     

HMW1 is required for stability and localization of HMW2 to the attachment organelle of Mycoplasma pneumoniae

The cytoskeletal proteins HMW1 and HMW2 are components of the terminal organelle of the cell wall-less bacterium Mycoplasma pneumoniae. HMW1 is required for a tapered, filamentous morphology but exhibits accelerated turnover in the absence of HMW2. Here, we report that a reciprocal dependency exists between HMW1 and HMW2, with HMW2 subject to accelerated turnover with the loss of HMW1. Furthermore, the instability of HMW2 correlated with its failure to localize to the attachment organelle. The C-terminal domain of HMW1 is essential for both function and its accelerated turnover in the absence of HMW2. We constructed HMW1 deletion derivatives lacking portions of this domain and examined each for stability and function. The C-terminal 41 residues were particularly important for proper localization and function in cell morphology and P1 localization, but the entire C-terminal domain was required to stabilize HMW2. The significance of these findings in the context of attachment organelle assembly is considered.     

Amino-terminal residues 1-45 of the Escherichia coli pyruvate dehydrogenase complex E1 subunit interact with the E2 subunit and are required for activity of the complex but not for reductive acetylation of the E2 subunit

While N-terminal amino acids 1-55 are not seen in the structure of the Escherichia coli pyruvate dehydrogenase complex E1 subunit (PDHc-E1), mass spectrometric analysis indicated that this amino-terminal region of PDHc-E1 was protected by PDHc-E2. Hence, five deletion constructs of PDHc-E1 were created, Delta6-15, Delta16-25, Delta26-35, Delta36-45, and Delta46-55, along with single-site substitutions at Asp7, Asp9, Pro10, Ile11, Glu12, Thr13, Arg14, and Asp15. The decarboxylation of pyruvate and the ability of PDHc-E1 to dimerize are not affected by any of the deletions or substitutions. While Delta46-55 and the Pro10Ala, Ile11Ala, and Thr13Ala variants could form a complex with PDHc-E2, and produced NADH in the overall assay, Delta16-25, Delta26-35, and Delta36-45 and the Asp7Ala, Asp9Ala, Glu12Gln, Glu12Asp, Arg14Ala, and Asp15Ala variants failed in both respects. Remarkably, all constructs of PDHc-E1 from E. coli, as well as PDHc-E1 from Mycobacterium tuberculosis, could carry out reductive acetylation of the E. coli lipoyl domain, but only constructs of the E. coli PDHc-E1 could reductively acetylate E. coli PDHc-E2. It was concluded that there are at least two loci of interaction between the PDHc-E1 and PDHc-E2 subunits: (1) the thiamin diphosphate-bound substrate on PDHc-E1 and the lipoylamide of PDHc-E2, as reflected by the ability to reductively acetylate the latter; and (2) amino terminal residues 1-45 of PDHc-E1 with regions of PDHc-E2 (so far undefined for the E. coli complex), as reflected by the overall activity of the entire complex. These studies add important information regarding recognition within this multienzyme complex class with an alpha(2) E1 assembly.