The 2024 Nucleic Acids Research database issue and the online molecular biology database collection.

The 2024 Nucleic Acids Research database issue contains 180 papers from across biology and neighbouring disciplines. There are 90 papers reporting on new databases and 83 updates from resources previously published in the Issue. Updates from databases most recently published elsewhere account for a further seven. Nucleic acid databases include the new NAKB for structural information and updates from Genbank, ENA, GEO, Tarbase and JASPAR. The Issue's Breakthrough Article concerns NMPFamsDB for novel prokaryotic protein families and the AlphaFold Protein Structure Database has an important update. Metabolism is covered by updates from Reactome, Wikipathways and Metabolights. Microbes are covered by RefSeq, UNITE, SPIRE and P10K; viruses by ViralZone and PhageScope. Medically-oriented databases include the familiar COSMIC, Drugbank and TTD. Genomics-related resources include Ensembl, UCSC Genome Browser and Monarch. New arrivals cover plant imaging (OPIA and PlantPAD) and crop plants (SoyMD, TCOD and CropGS-Hub). The entire Database Issue is freely available online on the Nucleic Acids Research website (https://academic.oup.com/nar). Over the last year the NAR online Molecular Biology Database Collection has been updated, reviewing 1060 entries, adding 97 new resources and eliminating 388 discontinued URLs bringing the current total to 1959 databases. It is available at http://www.oxfordjournals.org/nar/database/c/.

The next decade in structural biology.

As we celebrate the 30th anniversary of Structure, we have asked structural biologists about their expectations on how their respective fields are likely to develop in the next ten years in this collection of Voices.

Hallazgos incidentales en medicina genómica / Incidental Findings in Genomic Medicine

Las técnicas de Biología Molecular de última generación, como es la secuenciación masiva en paralelo o NGS (Next Generation Sequencing), permite obtener gran cantidad de información genómica, la cual muchas veces va más allá de la detección de una variante patogénica en un gen que explique la patología (hallazgo primario). Es así como surgió desde hace años la discusión internacional respecto a la decisión a tomar frente a los hallazgos secundarios accionables, es decir, aquellos hallazgos de variantes clasificadas como patogénicas o probablemente patogénicas que no están relacionadas con el fenotipo del paciente, pero que tiene alguna medida preventiva o tratamiento posible y, por lo tanto, podría ser de utilidad para la salud del paciente. Luego de revisar la bibliografía internacional y debatir entre los expertos del Hospital de Pediatría Garrahan, se logró establecer una política institucional y reforzar el hecho de que se trata de una disciplina multidisciplinaria. Así, fue posible definir que solo se atenderá las cuestiones relacionadas con la edad pediátrica, dejando para un tratamiento posterior aquellas variantes detectadas en genes que sean accionables en edad adulta. En el Hospital Garrahan, ha sido posible definir claramente cómo proceder frente a los hallazgos secundarios, al adaptar el consentimiento informado a esta necesidad, definiendo cuándo serán informados, y sabiendo que serán buscados intencionalmente en los genes clínicamente accionables enlistados en la última publicación del American College of Medical Genetics and Genomics, siempre y cuando el paciente/padre/tutor lo consienta (AU)

The latest generation of molecular biology techniques, including massive parallel sequencing or NGS (Next Generation Sequencing), allows us to obtain a whealth of genomic information, which often goes beyond the detection of a pathogenic variant in a gene that explains the pathology (primary finding). As a result, an international discussion has arisen over the years regarding the decision-making concerning actionable secondary findings, it means, those findings of variants classified as pathogenic or probably pathogenic that are not related to the patient's phenotype, but which have some possible preventive measure or treatment and, therefore, could be useful for the patient's health. After reviewing the international literature and discussing among the experts of the Hospital de Pediatría Garrahan, an institutional policy was established and the concept that this is a multidisciplinary discipline was reinforced. Consequently, it has been defined that only issues related to children will be addressed, reserving those variants detected in genes that are actionable in adulthood for later treatment. At Garrahan Hospital, we were able to clearly define how to proceed with secondary findings by adapting the informed consent to this need, defining when they will be reported, and knowing that they will be intentionally searched for in the clinically actionable genes listed in the latest publication of the American College of Medical Genetics and Genomics, as long as the patient/parent/guardian consents (AU)

Historical Advances in Structural and Molecular Biology and How They Impacted Vaccine Development.

Vaccines are among the greatest tools for prevention and control of disease. They have eliminated smallpox from the planet, decreased morbidity and mortality for major infectious diseases like polio, measles, mumps, and rubella, significantly blunted the impact of the COVID-19 pandemic, and prevented viral induced cancers such as cervical cancer caused by human papillomavirus. Recent technological advances, in genomics, structural biology, and human immunology have transformed vaccine development, enabling new technologies such as mRNA vaccines to greatly accelerate development of new and improved vaccines. In this review, we briefly highlight the history of vaccine development, and provide examples of where advances in genomics and structural biology, paved the way for development of vaccines for bacterial and viral diseases.

Voices on technology: The molecular biologists' ever-expanding toy box.

With the focus on technology for this issue of Molecular Cell, a group of scientists working in different areas of molecular biology provide their perspective on the most recent important technological advance in their field, where the field is lacking, and their wish list for future technology development.

Current Issues in Molecular Biology Journal Enters a New Era.

Current Issues in Molecular Biology (CIMB) (https://www [...].

Innovations in Neuro-Oncology.

Although outcomes for many brain tumors, especially glioblastomas, remain poor, there have been significant advances in clinical and scientific understanding of neuro-oncologic disease. Tumor molecular profiling has become a critical component of clinical practice, allowing more accurate pathologic diagnosis and enhanced clarity of the pathogenesis of both primary and metastatic brain tumors. The development of cerebral organoids carries exciting potential to provide representative models of tumor growth and potential drug efficacy, while new radiology techniques continue to improve clinical decision making. New adaptive trial platforms have been developed to rapidly test therapies and biomarkers with good scientific rationale. Lastly, growth and development of neuro-oncology clinical care teams aim to further improve patients' outcomes and symptoms, especially at the end of life.

The childhood migraine syndrome.

Migraine is a complex genetic brain disorder with an intricate pathogenesis and polymorphous clinical presentations, particularly in children. In this Perspective, we describe the different phenotypes of migraine in children, including conditions that have been referred to in the International Classification of Headache Disorders as "syndromes that may be related to migraine''. Evidence is presented for the integration of abdominal migraine, cyclical vomiting syndrome, benign paroxysmal vertigo, benign paroxysmal torticollis and infantile colic into the unified diagnosis of 'childhood migraine syndrome' on the basis of clinical and epidemiological characteristics, and shared inheritance. In our opinion, such integration will guide clinicians from specialities other than neurology to consider migraine in the assessment of children with these disorders, as well as stimulate research into the genetics, pathophysiology and clinical features of all disorders within the syndrome. A diagnosis of childhood migraine syndrome would also enable patients to benefit from inclusion in clinical trials of old and new migraine treatments, thus potentially increasing the number of treatment options available.

Harnessing nanotechnology to expand the toolbox of chemical biology.

Although nanotechnology often addresses biomedical needs, nanoscale tools can also facilitate broad biological discovery. Nanoscale delivery, imaging, biosensing, and bioreactor technologies may address unmet questions at the interface between chemistry and biology. Currently, many chemical biologists do not include nanomaterials in their toolbox, and few investigators develop nanomaterials in the context of chemical tools to answer biological questions. We reason that the two fields are ripe with opportunity for greater synergy. Nanotechnologies can expand the utility of chemical tools in the hands of chemical biologists, for example, through controlled delivery of reactive and/or toxic compounds or signal-binding events of small molecules in living systems. Conversely, chemical biologists can work with nanotechnologists to address challenging biological questions that are inaccessible to both communities. This Perspective aims to introduce the chemical biology community to nanotechnologies that may expand their methodologies while inspiring nanotechnologists to address questions relevant to chemical biology.

Mathematical Modelling in Biomedicine: A Primer for the Curious and the Skeptic.

In most disciplines of natural sciences and engineering, mathematical and computational modelling are mainstay methods which are usefulness beyond doubt. These disciplines would not have reached today's level of sophistication without an intensive use of mathematical and computational models together with quantitative data. This approach has not been followed in much of molecular biology and biomedicine, however, where qualitative descriptions are accepted as a satisfactory replacement for mathematical rigor and the use of computational models is seen by many as a fringe practice rather than as a powerful scientific method. This position disregards mathematical thinking as having contributed key discoveries in biology for more than a century, e.g., in the connection between genes, inheritance, and evolution or in the mechanisms of enzymatic catalysis. Here, we discuss the role of computational modelling in the arsenal of modern scientific methods in biomedicine. We list frequent misconceptions about mathematical modelling found among biomedical experimentalists and suggest some good practices that can help bridge the cognitive gap between modelers and experimental researchers in biomedicine. This manuscript was written with two readers in mind. Firstly, it is intended for mathematical modelers with a background in physics, mathematics, or engineering who want to jump into biomedicine. We provide them with ideas to motivate the use of mathematical modelling when discussing with experimental partners. Secondly, this is a text for biomedical researchers intrigued with utilizing mathematical modelling to investigate the pathophysiology of human diseases to improve their diagnostics and treatment.

Capturing and Understanding the Dynamics and Heterogeneity of Gene Expression in the Living Cell.

The regulation of gene expression is a fundamental process enabling cells to respond to internal and external stimuli or to execute developmental programs. Changes in gene expression are highly dynamic and depend on many intrinsic and extrinsic factors. In this review, we highlight the dynamic nature of transient gene expression changes to better understand cell physiology and development in general. We will start by comparing recent in vivo procedures to capture gene expression in real time. Intrinsic factors modulating gene expression dynamics will then be discussed, focusing on chromatin modifications. Furthermore, we will dissect how cell physiology or age impacts on dynamic gene regulation and especially discuss molecular insights into acquired transcriptional memory. Finally, this review will give an update on the mechanisms of heterogeneous gene expression among genetically identical individual cells. We will mainly focus on state-of-the-art developments in the yeast model but also cover higher eukaryotic systems.

New era of trophoblast research: integrating morphological and molecular approaches.

Many pregnancy complications are the result of dysfunction in the placenta. The pathogenic mechanisms of placenta-mediated pregnancy complications, however, are unclear. Abnormal placental development in these conditions begins in the first trimester, but no symptoms are observed during this period. To elucidate effective preventative treatments, understanding the differentiation and development of human placenta is crucial. This review elucidates the uniqueness of the human placenta in early development from the aspect of structural characteristics and molecular markers. We summarise the morphogenesis of human placenta based on human specimens and then compile molecular markers that have been clarified by immunostaining and RNA-sequencing data across species. Relevant studies were identified using the PubMed database and Google Scholar search engines up to March 2020. All articles were independently screened for eligibility by the authors based on titles and abstracts. In particular, the authors carefully examined literature on human placentation. This review integrates the development of human placentation from morphological approaches in comparison with other species and provides new insights into trophoblast molecular markers. The morphological features of human early placentation are described in Carnegie stages (CS), from CS3 (floating blastocyst) to CS9 (emerging point of tertiary villi). Molecular markers are described for each type of trophoblast involved in human placental development. We summarise the character of human trophoblast cell lines and explain how long-term culture system of human cytotrophoblast, both monolayer and spheroid, established in recent studies allows for the generation of human trophoblast cell lines. Due to differences in developmental features among species, it is desirable to understand early placentation in humans. In addition, reliable molecular markers that reflect normal human trophoblast are needed to advance trophoblast research. In the clinical setting, these markers can be valuable means for morphologically and functionally assessing placenta-mediated pregnancy complications and provide early prediction and management of these diseases.

[RNAissance: is there a future for RNA therapeutics?] / RNAissance: is er een toekomst voor RNA-therapeutica?

The central dogma in molecular biology states that genetic information is transmitted from DNA to RNA to proteins, but not the other way round. Thanks to a recent technological revolution - the 'RNAissance' - it has, however, become clear that RNA is not solely a messenger for passing on the genetic information necessary for protein synthesis, but that RNA also plays an important role in sickness and health. In the past 5 years alone more than 100 therapies with (complementary) RNA molecules have been investigated in Phase 1 trials, and a quarter of these have also been investigated in Phase 2 or 3 trials. The dramatic increase in the number of pharmaceutical companies that are developing RNA therapeutics illustrates the enormous potential of these medicines. Once the toxicity and the costs of RNA therapeutics can be limited, these medicines - personalized or not - could soon be prescribed for patients with a wide range of chronic conditions.

[Junk DNA is out of fashion]. / Chroniques génomiques - Le Junk DNA n'est plus ce qu'il était.

A systematic search for non-conventional open reading frames in human DNA reveals a large number of small ORFs encoding peptides generally smaller than 100 amino-acids. These ORFs are transcribed and translated into small proteins, which are demonstrated to have functional significance by bulk CRISPR inactivation. Evidence is also found for bicistronic mRNAs including such a small ORF upstream of a canonical coding sequence. These findings add a new facet to our understanding of biological processes.