Biópsia embrionária: qual a melhor escolha? / Embryo biopsy: what is the best choice?

Introdução: a biópsia embrionária tem como objetivo selecionar embriões geneticamente normais. Essa seleção ocorre por meio de testes genéticos pré-implantacionais. Espera-se, com isso, uma diminuição dos riscos de doenças genéticas e um aumento das taxas de implantação em fertilização in vitro. Objetivo: verificar, por meio de revisão bibliográfica, qual técnica de biópsia embrionária é considerada mais apropriada para feitura de testes genéticos pré-implantacionais. Método: pesquisa bibliográfica, na forma de revisão de publicações científicas, por meio das redes US National Library of Medicine (Pubmed), Literatura Latino-Americana e do Caribe em Ciências da Saúde (Lilacs), Google Acadêmico e Biblioteca Virtual em Saúde (BVS). Resultados e conclusão: existem três maneiras de efetuar a biópsia para reprodução humana assistida. A primeira consiste em retirar o primeiro e/ou o segundo corpúsculo polar estruído pelo oócito. Também se pode fazer a biópsia a partir de um blastômero do embrião em estágio de clivagem ou usar cinco a dez células do trofoectoderma de blastocisto. Normalmente as técnicas usadas para o diagnóstico são PCR, Fish, CGH array e SNP array, entre outras. Acredita-se que a biópsia de blastocistos é a melhor técnica para manter o potencial de implantação embrionária. Essa tendência se justifica por causa da maior quantidade de material genético disponível em fase avançada de desenvolvimento embrionário. Admite-se que nessa fase a incidência de mosaicismo seja menor em relação à biópsia de blastômeros, com consequente aumento na eficácia dos testes genéticos. Outra questão importante é que na biópsia de blastocistos as células são retiradas do trofoectoderma, enquanto que na biópsia em estágio de clivagem a remoção de um blastômero pode prejudicar o desenvolvimento embrionário.

Introduction: the embryo biopsy aims to select genetically normal embryos. This selection occurs through pre- implantation genetic testing. It is expected the reduction of risk ofgenetic disorders and increase implantation rates in IVF.Objective: to verify, through bibliographical revision, which embryo biopsy technique is considered more suitable for pre-implantation genetic diagnosis. Method: bibliographical research, in the form of literary review of scientific publications via networks, US National Library of Medicine (Pubmed), Latin-American Literature and Caribbean Health Sciences (Lilacs), Google Scholar and Virtual Health Library. Results and conclusion: there are three ways to perform the biopsy on assisted human reproduction.The first one consists in removing the 1st and/or 2nd polar body (if there wasfertilization). You can also perform the biopsy from the one blastomere of embryo cleavage stage or use 5-10 trophoectoderm cells blastocyst. Usually the techniques used for diagnosticpurpose are PCR, Fish, CGH array, SNP array and others. Nowadays it is believed that blastocyst biopsy is the best technique in order to maintain the embryonic implantation. This tendency is justified by the larger amount of genetic material available in an advancedstage of embryonic development. It is assumed that in this stage the incidence of mosaicism is reduced with the consequent increase in the effectiveness of genetic testing. Another important question is that the blastocyst biopsy cells are removed from the trophoectoderm while inbiopsy incleavage stage, the removal of one blastomere can impair embryonicdevelopment.

Negative feedback regulation of Wnt signaling by Gbetagamma-mediated reduction of Dishevelled

Wnt signaling is known to be important for diverse embryonic and post-natal cellular events and be regulated by the proteins Dishevelled and Axin. Although Dishevelled is activated by Wnt and involved in signal transduction, it is not clear how Dishevelled-mediated signaling is turned off. We report that guanine nucleotide binding protein beta 2 (Gnb2; Gbeta2) bound to Axin and Gbeta2 inhibited Wnt mediated reporter activity. The inhibition involved reduction of the level of Dishevelled, and the Gbeta2gamma2 mediated reduction of Dishevelled was countered by increased expression of Axin. Consistent with these effects in HEK293T cells, injection of Gbeta2gamma2 into Xenopus embryos inhibited the formation of secondary axes induced either by XWnt8 or Dishevelled, but not by beta-catenin. The DEP domain of Dishevelled is necessary for both interaction with Gbeta2gamma2 and subsequent degradation of Dishevelled via the lysosomal pathway. Signaling induced by Gbeta2gamma2 is required because a mutant of Gbeta2, Gbeta2 (W332A) with lower signaling activity, had reduced ability to downregulate the level of Dishevelled. Activation of Wnt signaling by either of two methods, increased Frizzled signaling or transient transfection of Wnt, also led to increased degradation of Dishevelled and the induced Dishevelled loss is dependent on Gbeta1 and Gbeta2. Other studies with agents that interfere with PLC action and calcium signaling suggested that loss of Dishevelled is mediated through the following pathway: Wnt/Frizzled-->Gbetagamma-->PLC-->Ca+2/PKC signaling. Together the evidence suggests a novel negative feedback mechanism in which Gbeta2gamma2 inhibits Wnt signaling by degradation of Dishevelled.

Conventional and novel methods for embryonic stem cell line derivation.

Cell therapy is the promising therapeutic tool for the next decade. "Regenerative Medicine" based on cell and tissue replacement therapy is proposed as a revolutionary approach to various chronic and incurable conditions. The first key step for successful cell therapy is the establishment of clinical grade human Embryonic Stem Cell (hESC) lines. This article provides a concise summary on conventional and novel methods for hESC line derivation. There is also discussion on progression, future direction and problems in hESC line development. In Thailand, more advance knowledge, skill, and technology are required to develop the first human embryonic stem cell line and step forward to make cell therapy a reality.

Reliable sex determination of mouse preimplantation embryos by PCR amplification of male-specific genes in single blastomeres.

OBJECTIVE: To assess the reliability of sex determination in mouse preimplantation embryos using the two-step polymerase chain reaction method. SETTING: Division of Immunology, Department of Microbiology and Division of Reproductive Medicine, Department of OB/GYN. METHODS: The Sry and Zfy genes, known to be present in the sex-determining region of mouse Y chromosome, were selected for Y-specific target sequences and DXNds 3 locus located on mouse X chromosome was served as the internal control sequence. DNAs extracted from heart blood of male and female mice were used to test the correctness and specificity of the selected primers using the two-step PCR method. The same experimental conditions were then used to amplify the single copy genes in single mouse blastomeres with two pairs of primers for each of the target sequences. The sex-determined embryos were transferred to the uteri of pseudopregnant recipients to test the consistency of the assay system. RESULTS: All male and female blood DNA sample results confirmed the correct sex identification of the origin (100%). Nineteen of 20 single blastomeres showed the accurate diagnosis when compared with theirs 7/8 embryos. The sex of 36 of 37 mouse pups born from biopsied male and female embryos agreed with the predicted sex. CONCLUSION: The reliable genetic analysis of sex chromosome- specific sequences in single cell is possible by the two-step PCR method and could be applied for diagnosis of defective genes of human preimplantation embryos derived from the in vitro fertilization program.