M. J. D. White

Two distinct pathways regulate platelet phosphatidylserine exposure and procoagulant function

Procoagulant platelets exhibit hallmark features of apoptotic cells, including membrane blebbing, microvesiculation, and phosphatidylserine (PS) exposure. Although platelets possess many well-known apoptotic regulators, their role in regulating the procoagulant function of platelets is unclear. To clarify this, we investigated the consequence of removing the essential mediators of apoptosis, Bak and Bax, or directly inducing apoptosis with the BH3 mimetic compound ABT-737. Treatment of platelets with ABT-737 triggered PS exposure and a marked increase in thrombin generation in vitro. This increase in procoagulant function was Bak/Bax- and caspase-dependent, but it was unaffected by inhibitors of platelet activation or by chelating extracellular calcium. In contrast, agonist-induced platelet procoagulant function was unchanged in Bak(-/-)Bax(-/-) or caspase inhibitor-treated platelets, but it was completely eliminated by extracellular calcium chelators or inhibitors of platelet activation. These studies show the existence of 2 distinct pathways regulating the procoagulant function of platelets.

Megakaryocytes possess a functional intrinsic apoptosis pathway that must be restrained to survive and produce platelets

Deletion of Bak and Bax, the effectors of mitochondrial apoptosis, does not affect platelet production, however, loss of prosurvival Bcl-xL results in megakaryocyte apoptosis and failure of platelet shedding.

Cytogenetics of Orthopteroid Insects

Publisher Summary The term Orthopteroid insects is employed in this chapter to designate the miscellaneous assemblage of forms commonly called Orthoptera. This chapter presents a systematic review of the cytology of the orthopteroida. It discusses the chromosomes and taxonomy in the orthopteroid groups, cytological polymorphism in the orthopteroid insects, and parthenogenesis in the orthopteroid groups. Visible cytological differences between the closely related species are rare in the Orthopteroid groups. However, in certain groups of Orthoptera the visible cytological differences between the closely related forms are considerable. The centromeres of all orthopterous chromosomes seem to be strictly localized structures. Two kinds of chromosomal elements occur: (1) rod-shaped chromosomes, and (2) J-shaped or V-shaped elements. The meiotic divisions of most of the Orthoptera follow the “typical” or “normal” course— that is, to say the anomalous modifications of the meiotic divisions that occur in so many of the Diptera, Scale Insects, Lice, and other orders of insects are not known to occur in the Orthopteroid groups. In few species of Orthopteroid insects, parthenogenesis is the normal method of reproduction; males being either unknown or extremely rare. Apart from these cases, there are a number of instances on record in which unfertilized eggs of normally bisexual species are known to have undergone development.

Mitochondrial apoptosis is dispensable for NLRP3 inflammasome activation but non‐apoptotic caspase‐8 is required for inflammasome priming

A current paradigm proposes that mitochondrial damage is a critical determinant of NLRP3 inflammasome activation. Here, we genetically assess whether mitochondrial signalling represents a unified mechanism to explain how NLRP3 is activated by divergent stimuli. Neither co‐deletion of the essential executioners of mitochondrial apoptosis BAK and BAX, nor removal of the mitochondrial permeability transition pore component cyclophilin D, nor loss of the mitophagy regulator Parkin, nor deficiency in MAVS affects NLRP3 inflammasome function. In contrast, caspase‐8, a caspase essential for death‐receptor‐mediated apoptosis, is required for efficient Toll‐like‐receptor‐induced inflammasome priming and cytokine production. Collectively, these results demonstrate that mitochondrial apoptosis is not required for NLRP3 activation, and highlight an important non‐apoptotic role for caspase‐8 in regulating inflammasome activation and pro‐inflammatory cytokine levels.

Heterozygosity and Genetic Polymorphism in Parthenogenetic Animals

The name of Th. Dobzhansky will always be associated with the concepts of heterosis and adaptive genetic polymorphisms in natural populations of sexually reproducing organisms. But the relationship between these concepts is still in part controversial and even after approximately 35 years of serious study of these phenomena in a variety of organisms, both in nature and in the laboratory, it is by no means clear how far the adaptive significance of most polymorphisms is to be ascribed to “pure heterosis” (i.e., superiority of the heterozygote in all environments) and how far to “annidation” (in the terminology of Ludwig, 1950)—i.e., an adaptive correspondence between the various genotypes present in the population and the alternative ecological niches present in the environment.

Cytogenetics of the parthenogenetic grasshopper Warramaba (formerly Moraba) virgo and its bisexual relatives

The distribution of late-replicating segments along the chromosomes of five clones of W. virgo is described. Some, but not all of these segments correspond to C-bands. In general, the “autoradiographic profiles” (histograms of linear grain density along the length of chromosomes labeled with tritiated thymidine in late S-phase) show strong resemblances throughout the five clones. However, some significant differences exist, and these are particularly marked in the case of the Boulder clone, which is anomalous in many other respects. — A similar study has also been carried out on the two bisexual species of Warramaba (“P169” and “P196”) that gave rise, by hybridization more than half a million years ago, to the parthenogenetic W. virgo. In the case of P169, the autoradiographic profiles of the three large chromosomes (X+A, B+5, CD) which it has contributed to the W. virgo karyotype are extremely similar to those of the corresponding chromosomes in the virgo clones we have studied. In the case of P196 there is likewise, in most instances, a close resemblance of the autoradiographic profiles of the AB, X1 and CD chromosomes to those of the same chromosomes in the virgo clones, but that of the X1 shows no particular resemblance to the anomalous profile of the X1 in the Boulder clone, in which the X1 has undergone a structural reorganisation. The autoradiographic profile of the P196 CD chromosome does, however, show a much closer resemblance to that of the corresponding chromosome in the Boulder clone than to those of the CD196 in the other four virgo clones studied. These investigations confirm the considerable evolutionary stability of DNA replication patterns.

Caspase-9 mediates the apoptotic death of megakaryocytes and platelets, but is dispensable for their generation and function

Apoptotic caspases, including caspase-9, are thought to facilitate platelet shedding by megakaryocytes. They are known to be activated during platelet apoptosis, and have also been implicated in platelet hemostatic responses. However, the precise requirement for, and the regulation of, apoptotic caspases have never been defined in either megakaryocytes or platelets. To establish the role of caspases in platelet production and function, we generated mice lacking caspase-9 in their hematopoietic system. We demonstrate that both megakaryocytes and platelets possess a functional apoptotic caspase cascade downstream of Bcl-2 family-mediated mitochondrial damage. Caspase-9 is the initiator caspase, and its loss blocks effector caspase activation. Surprisingly, steady-state thrombopoiesis is unperturbed in the absence of caspase-9, indicating that the apoptotic caspase cascade is not required for platelet production. In platelets, loss of caspase-9 confers resistance to the BH3 mimetic ABT-737, blocking phosphatidylserine (PS) exposure and delaying ABT-737-induced thrombocytopenia in vivo. Despite this, steady-state platelet lifespan is normal. Casp9(-/-) platelets are fully capable of physiologic hemostatic responses and functional regulation of adhesive integrins in response to agonist. These studies demonstrate that the apoptotic caspase cascade is required for the efficient death of megakaryocytes and platelets, but is dispensable for their generation and function.

Individual and overlapping roles of BH3-only proteins Bim and Bad in apoptosis of lymphocytes and platelets and in suppression of thymic lymphoma development

BH3-only proteins, such as Bim and Bad, contribute to tissue homeostasis by initiating apoptosis in a cell type- and stimulus-specific manner. Loss of Bim provokes lymphocyte accumulation in vivo and renders lymphocytes more resistant to diverse apoptotic stimuli and Bad has been implicated in the apoptosis of haematopoietic cells upon cytokine deprivation. To investigate whether their biological roles in apoptosis overlap, we generated mice lacking both Bim and Bad and compared their haematopoietic phenotype with that of the single-knockout and wild-type (wt) animals. Unexpectedly, bad−/− mice had excess platelets due to prolonged platelet life-span. The bim−/−bad−/− mice were anatomically normal and fertile. Their haematopoietic phenotype resembled that of bim−/− mice but lymphocytes were slightly more elevated in their lymph nodes. Although resting B and T lymphocytes from bim−/−bad−/− and bim−/− animals displayed similar resistance to diverse apoptotic stimuli, mitogen activated bim−/−bad−/− B cells were more refractory to cytokine deprivation. Moreover, combined loss of Bim and Bad-enhanced survival of thymocytes after DNA damage and accelerated development of γ-irradiation-induced thymic lymphoma. Unexpectedly, their cooperation in the thymus depended upon thymocyte–stromal interaction. Collectively, these results show that Bim and Bad can cooperate in the apoptosis of thymocytes and activated B lymphocytes and in the suppression of thymic lymphoma development.

Mcl-1 and Bcl-xL coordinately regulate megakaryocyte survival

Mature megakaryocytes depend on the function of Bcl-x(L), a member of the Bcl-2 family of prosurvival proteins, to proceed safely through the process of platelet shedding. Despite this, loss of Bcl-x(L) does not prevent the growth and maturation of megakaryocytes, suggesting redundancy with other prosurvival proteins. We therefore generated mice with a megakaryocyte-specific deletion of Mcl-1, which is known to be expressed in megakaryocytes. Megakaryopoiesis, platelet production, and platelet lifespan were unperturbed in Mcl-1(Pf4Δ/Pf4Δ) animals. However, treatment with ABT-737, a BH3 mimetic compound that inhibits the prosurvival proteins Bcl-2, Bcl-x(L), and Bcl-w resulted in the complete ablation of megakaryocytes and platelets. Genetic deletion of both Mcl-1 and Bcl-x(L) in megakaryocytes resulted in preweaning lethality. Megakaryopoiesis in Bcl-x(Pf4Δ/Pf4Δ) Mcl-1(Pf4Δ/Pf4Δ) embryos was severely compromised, and these animals exhibited ectopic bleeding. Our studies indicate that the combination of Bcl-x(L) and Mcl-1 is essential for the viability of the megakaryocyte lineage.

Mcl-1 and Bcl-xL co-ordinately regulate megakaryocyte survival

Mature megakaryocytes depend on the function of Bcl-x(L), a member of the Bcl-2 family of prosurvival proteins, to proceed safely through the process of platelet shedding. Despite this, loss of Bcl-x(L) does not prevent the growth and maturation of megakaryocytes, suggesting redundancy with other prosurvival proteins. We therefore generated mice with a megakaryocyte-specific deletion of Mcl-1, which is known to be expressed in megakaryocytes. Megakaryopoiesis, platelet production, and platelet lifespan were unperturbed in Mcl-1(Pf4Δ/Pf4Δ) animals. However, treatment with ABT-737, a BH3 mimetic compound that inhibits the prosurvival proteins Bcl-2, Bcl-x(L), and Bcl-w resulted in the complete ablation of megakaryocytes and platelets. Genetic deletion of both Mcl-1 and Bcl-x(L) in megakaryocytes resulted in preweaning lethality. Megakaryopoiesis in Bcl-x(Pf4Δ/Pf4Δ) Mcl-1(Pf4Δ/Pf4Δ) embryos was severely compromised, and these animals exhibited ectopic bleeding. Our studies indicate that the combination of Bcl-x(L) and Mcl-1 is essential for the viability of the megakaryocyte lineage.