An oocyte meiotic midbody cap is required for developmental competence in mice.

Embryo development depends upon maternally derived materials. Mammalian oocytes undergo extreme asymmetric cytokinesis events, producing one large egg and two small polar bodies. During cytokinesis in somatic cells, the midbody and subsequent assembly of the midbody remnant, a signaling organelle containing RNAs, transcription factors and translation machinery, is thought to influence cellular function or fate. The role of the midbody and midbody remnant in gametes, in particular, oocytes, remains unclear. Here, we examined the formation and function of meiotic midbodies (mMB) and mMB remnants using mouse oocytes and demonstrate that mMBs have a specialized cap structure that is orientated toward polar bodies. We show that that mMBs are translationally active, and that mMB caps are required to retain nascent proteins in eggs. We propose that this specialized mMB cap maintains genetic factors in eggs allowing for full developmental competency.

An oocyte meiotic midbody cap is required for developmental competence in mice.

Embryo development depends upon maternally derived materials. Mammalian oocytes undergo extreme asymmetric cytokinesis events, producing one large egg and two small polar bodies (PB). During cytokinesis in somatic cells, the midbody (MB) and subsequent assembly of the midbody remnant (MBR), a signaling organelle containing RNAs, transcription factors and translation machinery, is thought to influence cellular function or fate. The role of the MB and MBR in gametes, in particular, oocytes, remains unclear. Here, we examined the formation and function of meiotic MBs (mMB) and mMB remnants (mMBRs) using mouse oocytes and demonstrate that mMBs have a specialized meiotic mMB cap structure that is orientated toward PBs. We show that that mMBs are translationally active, and that mMB caps are required to retain nascent proteins in eggs. We propose that this specialized mMB cap maintains genetic factors in eggs allowing for full developmental competency.

Multi-Photon Laser Ablation of Cytoplasmic Microtubule Organizing Centers in Mouse Oocytes.

The fidelity of oocyte meiosis is critical for generating developmentally competent euploid eggs. In mammals, the oocyte undergoes a lengthy arrest at prophase I of the first meiotic division. After puberty and upon meiotic resumption, the nuclear membrane disassembles (nuclear envelope breakdown), and the spindle is assembled mainly at the oocyte center. Initial central spindle positioning is essential to protect against abnormal kinetochore-microtubule (MT) attachments and aneuploidy. The centrally positioned spindle migrates in a time-sensitive manner toward the cortex, and this is a necessary process to extrude a tiny polar body. In mitotic cells, spindle positioning relies on the interaction between centrosome-mediated astral MTs and the cell cortex. On the contrary, mouse oocytes lack classic centrosomes and, instead, contain numerous acentriolar MT organizing centers (MTOCs). At the metaphase I stage, mouse oocytes have two different sets of MTOCs: (1) MTOCs that are clustered and sorted to assemble spindle poles (polar MTOCs), and (2) metaphase cytoplasmic MTOCs (mcMTOCs) that remain in the cytoplasm and do not contribute directly to spindle formation but play a crucial role in regulating spindle positioning and timely spindle migration. Here, a multi-photon laser ablation method is described to selectively deplete endogenously labeled mcMTOCs in oocytes collected from Cep192-eGfp reporter mice. This method contributes to the understanding of the molecular mechanisms underlying spindle positioning and migration in mammalian oocytes.

Microtubule organizing centers regulate spindle positioning in mouse oocytes.

During female meiosis I (MI), spindle positioning must be tightly regulated to ensure the fidelity of the first asymmetric division and faithful chromosome segregation. Although the role of F-actin in regulating these critical processes has been studied extensively, little is known about whether microtubules (MTs) participate in regulating these processes. Using mouse oocytes as a model system, we characterize a subset of MT organizing centers that do not contribute directly to spindle assembly, termed mcMTOCs. Using laser ablation, STED super-resolution microscopy, and chemical manipulation, we show that mcMTOCs are required to regulate spindle positioning and faithful chromosome segregation during MI. We discuss how forces exerted by F-actin on the spindle are balanced by mcMTOC-nucleated MTs to anchor the spindle centrally and to regulate its timely migration. Our findings provide a model for asymmetric cell division, complementing the current F-actin-based models, and implicate mcMTOCs as a major player in regulating spindle positioning.

Hipercetonemia: bioquímica de la producción de ácidos grasos volátiles y su metabolismo hepático / Hyperketonemia: Biochemistry of volatile fatty acid production and its hepatic metabolism

RESUMEN La hipercetonemia o cetosis bovina es un desorden metabólico, que se caracteriza por el incremento patológico de cuerpos cetónicos (beta-hidroxibutirato (βHB), Acetoacetato (AcAc) y acetona) y ocurre en el periparto de vacas de leche. El origen primario de la enfermedad es el balance energético negativo (BEN), que puede ser desencadenado por el incremento excesivo de los requerimientos energéticos o la presentación de enfermedades posparto, resultando en la presentación de signos clínicos o disminución de la producción de leche. El objetivo de esta revisión consiste en describir, mediante un modelo, los procesos bioquímicos del rumen y los mecanismos fisiopatológicos, involucrados con incremento excesivo de los cuerpos cetónicos. En resumen, se realizó un modelo fisiológico uniendo literatura fragmentada, sobre la relación entre la función ruminal, hepática y la inducción de lipolisis e incremento de la actividad de Carnitil-Palmitoil transferasa-1 (CPT-1), cuyo resultado puede ser la producción excesiva de Acetil-CoA que, junto con la falta de propionato y oxalacetato (precursores de gluconeogénesis y ciclo de Krebs), dan lugar a la producción patológica de acetoacetato y beta-hidroxibutirato.

ABSTRACT Bovine hyperketonemia or ketosis is a metabolic disorder characterized by high levels of ketone bodies (beta-hydroxybutyrate (βHB), Acetoacetate (AcAc), and acetone) in periparturient dairy cows. A Negative Energy Balance (NEB) is identified as the primary cause of the disease, which is triggered by the excessive increase of energy requirements or the presence of postpartum diseases, resulting in the appearance of clinical signs or decreased milk production. The purpose of this review is to describe the rumen's biochemical Process and the physiopathological mechanisms involved in the excessive production of ketone bodies. After conducting a literature review, a physiological model was carried out in order to understand the relationship between the rumen and liver functions with lipolysis induction and increased CPT-1 activity. The above may result in the overproduction of Acetyl-CoA, which together, with the lack of propionate and oxaloacetate (gluconeogenesis and Krebs cycle precursors), leads to the pathological production of acetoacetate and beta-hydroxybutyrate.