Dipetalonema viteae: isoelectric focusing and immunochemical studies on somatic extracts of adult worms and microfilariae.

Isoelectric focusing (IEF) of a somatic extract of adult worms (SEAW) yielded nine fractions. Most of the applied protein antigen was recovered in five fractions with pI values of 5.2, 4.4, 4.3, 4.0, and 3.3, respectively. The nine IEF fractions of SEAW gave a total of 37 bands following electrophoresis on polyacrylamide gel (PAGE). IEF fractionation of a somatic extract of microfilariae (SEM) yielded nine fractions. Two fractions with pI values of 4.4 and 3.2, respectively, contained most of the applied protein. The nine IEF fractions of SEM gave a total of 32 bands following PAGE. Crossed immunoelectrophoresis (CI) of SEM and SEAW against serum from hyperinfected hamsters yielded five and eight precipitation peaks, respectively. CI of SEM and SEAW against their homologous rabbit antisera gave 7 and 10 major precipitation peaks, respectively. Immunodiffusion of the nine IEF fractions from both SEM and SEAW against both their homologous and heterologous rabbit antisera indicated three and four precipitin bands peculiar only to SEM and SEAW, respectively. The remaining 23 bands from both preparations showed lines of identity.     

Contributions of dangling end stacking and terminal base-pair formation to the stabilities of XGGCCp, XCCGGp, XGGCCYp, and XCCGGYp helixes

The role of stacking in terminal base-pair formation was studied by comparison of the stability increments for dangling ends to those for fully formed base pairs. Thermodynamic parameters were measured spectrophotometrically for helix formation of the hexanucleotides AGGCCUp, UGGCCAp, CGGCCGp, GCCGGCp, and UCCGGAp and for the corresponding pentanucleotides containing a 5'-dangling end on the GGCCp or CCGGp core helix. In 1 M NaCl at 1 X 10(-4) M strands, a 5'-dangling nucleotide in this series increases the duplex melting temperature (Tm) only 0-4 degrees C, about the same as adding a 5'-phosphate. In contrast, a 3'-dangling nucleotide increases the Tm at 1 X 10(-4) M strands 7-23 degrees C, depending on the sequence [Freier, S. M., Burger, B. J., Alkema, D., Neilson, T., & Turner, D. H. (1983) Biochemistry 22, 6198-6206]. These results are consistent with stacking patterns observed in A-form RNA. The stability increments from terminal A.U, C.G, or U.A base pairs on GGCC or a terminal U.A pair on CCGG are nearly equal to the sums of the stability increments from the corresponding dangling ends. This suggests stacking plays a large role in nucleic acid stability. The stability increment from the terminal base pairs in GCCGGCp, however, is about 5 times the sum of the corresponding dangling ends, suggesting hydrogen bonding can also make important contributions.     

The selection of effector T cell phenotype by contrasuppression modulates susceptibility to autoimmune injury

The genetic susceptibility to murine alpha TBM disease is a dominant trait that maps to H-2K. In previous studies we have shown that the critical difference between susceptible (SJL) and nonsusceptible (B10.S(8R] mice is the phenotype of the tubular Ag-specific effector T cells (TDTH). In SJL mice, these TDTH are Lyt-2+, whereas in B10.S(8R) mice the TDTH are L3T4+. These phenotypic differences have an important functional correlate: Lyt-2+ TDTH are nephritogenic, whereas L3T4+ TDTH are typically not nephritogenic. Both mouse strains have the potential to differentiate both L3T4+ and Lyt-2+ TDTH. The preferential selection of a single TDTH phenotype in each is the result of differential T cell regulation. In the present studies, we have examined the contribution of suppressor and contrasuppressor T cells in the regulation of TDTH phenotype selection. Our studies show that in both SJL and B10.(8R) mice, after exposure to Ag, a suppressor T cell subpopulation functions to inhibit the nephritogenic Lyt-2+ TDTH. In SJL, but not B10.S(8R) mice, this suppression is counterbalanced by Lyt-2+, Vicia Villosa lectin-adherent T cells. Such contrasuppressor function is mediated through a T cell-derived soluble protein (TcsF), which is Ag-binding and recognized by alpha I-JS antisera. This functional TcsF activity maps, as does susceptibility to disease, to H-2K. In the presence of genetically compatible TcsF, the TDTH phenotype in nonsusceptible mice switches to that of susceptible mice. These Lyt-2+ TDTH from nonsusceptible mice are fully capable of inducing tubulointerstitial nephritis following adoptive transfer. Our studies describe a new role for Tcs cells and augment our understanding of their etiopathogenetic role in autoimmunity.     

Targeting the cell cycle in breast cancer: towards the next phase

Deregulation of the cell cycle is a hallmark of cancer that enables limitless cell division. To support this malignant phenotype, cells acquire molecular alterations that abrogate or bypass control mechanisms in signaling pathways and cellular checkpoints that normally function to prevent genomic instability and uncontrolled cell proliferation. Consequently, therapeutic targeting of the cell cycle has long been viewed as a promising anti-cancer strategy. Until recently, attempts to target the cell cycle for cancer therapy using selective inhibitors have proven unsuccessful due to intolerable toxicities and a lack of target specificity. However, improvements in our understanding of malignant cell-specific vulnerabilities has revealed a therapeutic window for preferential targeting of the cell cycle in cancer cells, and has led to the development of agents now in the clinic. In this review, we discuss the latest generation of cell cycle targeting anti-cancer agents for breast cancer, including approved CDK4/6 inhibitors, and investigational TTK and PLK4 inhibitors that are currently in clinical trials. In recognition of the emerging population of ER+ breast cancers with acquired resistance to CDK4/6 inhibitors we suggest new therapeutic avenues to treat these patients. We also offer our perspective on the direction of future research to address the problem of drug resistance, and discuss the mechanistic insights required for the successful implementation of these strategies.     

Glutathione transferases catalyze recycling of auto‐toxic cyanogenic glucosides in sorghum

Cyanogenic glucosides are nitrogen‐containing specialized metabolites that provide chemical defense against herbivores and pathogens via the release of toxic hydrogen cyanide. It has been suggested that cyanogenic glucosides are also a store of nitrogen that can be remobilized for general metabolism via a previously unknown pathway. Here we reveal a recycling pathway for the cyanogenic glucoside dhurrin in sorghum (Sorghum bicolor) that avoids hydrogen cyanide formation. As demonstrated in vitro, the pathway proceeds via spontaneous formation of a dhurrin‐derived glutathione conjugate, which undergoes reductive cleavage by glutathione transferases of the plant‐specific lambda class (GSTLs) to produce p‐hydroxyphenyl acetonitrile. This is further metabolized to p‐hydroxyphenylacetic acid and free ammonia by nitrilases, and then glucosylated to form p‐glucosyloxyphenylacetic acid. Two of the four GSTLs in sorghum exhibited high stereospecific catalytic activity towards the glutathione conjugate, and form a subclade in a phylogenetic tree of GSTLs in higher plants. The expression of the corresponding two GSTLs co‐localized with expression of the genes encoding the p‐hydroxyphenyl acetonitrile‐metabolizing nitrilases at the cellular level. The elucidation of this pathway places GSTs as key players in a remarkable scheme for metabolic plasticity allowing plants to reverse the resource flow between general and specialized metabolism in actively growing tissue.     

Axonal cytoskeletal changes after non-disruptive axonal injury

In animal models of human diffuse axonal injury, axonal swellings leading to secondary axotomy occur between 2 and 6 h after injury. But, analysis of cytoskeletal changes associated with secondary axotomy has not been undertaken. We have carried out a quantitative analysis of cytoskeletal changes in a model of diffuse axonal injury 4 h after stretch-injury to adult guinea-pig optic nerves. The major site of axonal damage was the middle portion of the nerve. There was a statistically significant increase in the proportion of small axons with a diameter of 0.5 μm and smaller in which there was compaction of neurofilaments. Axons with a diameter greater than 2.0 μm demonstrated an increased spacing between cytoskeletal elements throughout the length of the nerve. However, in the middle segment of the nerve these larger axons demonstrated two different types of response. Either, where periaxonal spaces occurred, there was a reduction in axonal calibre, compaction of neurofilaments but no change in their number, and a loss of microtubules. Or, where intramyelinic spaces occurred there was an increased spacing between neurofilaments and microtubules with a significant loss in the number of both. Longitudinal sections showed foci of compaction of neurofilaments interspersed between regions where axonal structure was apparently normal. Neurofilament compaction was correlated with disruption of the axolemma at these foci present some hours after injury. We suggest that the time course of these axonal cytoskeletal changes after stretch-injury to central axons is shorter than those changes documented to occur during Wallerian degeneration.