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A Practical Guide to Creating and Sustaining a Culture of Disciple-Making in Any Church Over the last few decades American churches have produced plenty of converts but not as many mature believers. Studies show the majority of Christians don’t even understand the basics of faith. But how do you tackle such a big problem? Replicate shows church leaders how to make disciples who make disciples and get the rest of your church on board as well. This one-on-one relational ministry is how Jesus laid the foundation for His church that is still growing today, and it’s how we continue the work in our own local congregations. Learn the five marks of a healthy disciple-making church, how to influence culture, uproot misconceptions of the church and the gospel, and change your church and community. No more focusing on mere numbers, it’s time to grow in maturity and through multiplication.
One of the pathways by which the scientific community confirms the validity of a new scientific discovery is by repeating the research that produced it. When a scientific effort fails to independently confirm the computations or results of a previous study, some fear that it may be a symptom of a lack of rigor in science, while others argue that such an observed inconsistency can be an important precursor to new discovery. Concerns about reproducibility and replicability have been expressed in both scientific and popular media. As these concerns came to light, Congress requested that the National Academies of Sciences, Engineering, and Medicine conduct a study to assess the extent of issues related to reproducibility and replicability and to offer recommendations for improving rigor and transparency in scientific research. Reproducibility and Replicability in Science defines reproducibility and replicability and examines the factors that may lead to non-reproducibility and non-replicability in research. Unlike the typical expectation of reproducibility between two computations, expectations about replicability are more nuanced, and in some cases a lack of replicability can aid the process of scientific discovery. This report provides recommendations to researchers, academic institutions, journals, and funders on steps they can take to improve reproducibility and replicability in science.
This book offers a general review of the voluminous theoretical and experimental literature pertaining to physical self-replicating systems. The principal focus here is on self-replicating machine systems. Most importantly, we are concerned with kinematic self-replicating machines: systems in which actual physical objects, not mere patterns of information, undertake their own replication. Following a brief burst of activity in the 1950s and 1980s, the field of kinematic replicating systems design received new interest in the 1990s with the emerging recognition of the feasibility of molecular nanotechnology. The field has experienced a renaissance of research activity since 1999 as researchers have come to recognize that replicating systems are simple enough to permit experimental laboratory demonstrations of working devices.
A girl discovers her geneticist father is covering up multiple secrets—all of which are named Jason. Jason 3:3—known as Martyr—always believed his life had purpose. As one of the hundreds of clones living in a closed-off underground facility beneath an Alaskan farm, he has been told his genetics hold the key to saving humanity from an airborne pandemic aboveground, and his purpose will be filled on his upcoming eighteenth birthday. The problem is no such pandemic exists. Unaware of the truth, Martyr wishes for one glimpse of the sky before his expiration date arrives. His escape leads him to the home of one of the scientists, and to Abby Goyer. As she helps Martyr, she can’t help but notice his uncanny resemblance to the high school quarterback. Abby soon uncovers the dark truth behind Jason Farms and her dad’s work, and decides to show Martyr his true value and worth. As Martyr learns the truth behind his existence, he must decide if his God-given purpose is connected to the farm, or if it rests in a life with Abby.
DNA replication is a key event in the cell cycle. Although our knowledge is far from complete and many elusive regulatory mechanisms still remain beyondour grasp, many enzymes and a multiplicity of biochemical mechanisms involved have been discovered. Recent findings in E. coli have confirmed and yet surpassed the original hypothesis of F. Jacob. In yeast and higher eucaryotes, the apparent redundancy in putative origins and initiators has made an estimation of the importance of each identified element difficult to access. In spite of well established methodologies - which are also described in the book - the origin identification in mammalian chromosomes is still a controversial subject. On the other hand, considerable advances have been made in our understanding of virus DNA replication and this continues to deepen and broaden our understanding of the controls of cellular DNA replication.
Consistency models for replicated data /Alan D. Fekete and Krithi Ramamritham --Replication techniques for availability /Robbert van Renesse and Rachid Guerraoui --Modular approach to replication for availability /Fernando Pedone and André Schiper --Stumbling over consensus research: misunderstandings and issues /Marcos K. Aguilera --Replicating for performance: case studies /Maarten van Steen and Guillaume Pierre --A history of the virtual synchrony replication model /Ken Birman --From viewstamped replication to byzantine fault tolerance /Barbara Liskov --Implementing trustworthy services using replicated state machines /Fred B. Schneider and Lidong Zhou --State machine replication with Byzantine faults /Christian Cachin --Selected results from the latest decade of quorum systems research /Michael G. Merideth and Michael K. Reiter --From object replication to database replication /Fernando Pedone and André Schiper --Database replication: a tutorial /Dettina Kemme, Ricardo Jiménez-Peris, Marta Patiño-Martínez, and Gustavo Alonso --Practical database replication /Alfrânio Correia Jr. ... [et al.].
There has been a sea change in how we view genetic recombination. When germ cells are produced in higher organisms, genetic recombination assures the proper segregation of like chromosomes. In the course of that process, called meiosis, recombination not only assures segregation of one chromosome of each type to progeny germ cells, but also further shuffles the genetic deck, contributing to the unique inheritance of individuals. In a nutshell, that is the classical view of recombination. We have also known for many years that in bacteria recombination plays a role in horizontal gene transfer and in replication itself, the latter by establishing some of the replication forks that are the structural scaffolds for copying DNA. In recent years, however, we have become increasingly aware that replication, which normally starts without any help from recombination, is a vulnerable process that frequently leads to broken DNA. The enzymes of recombination play a vital role in the repair of those breaks. The recombination enzymes can function via several different pathways that mediate the repair of breaks, as well as restoration of replication forks that are stalled by other kinds of damage to DNA. Thus, to the classical view of recombination as an engine of inheritance we must add the view of recombination as a vital housekeeping function that repairs breaks suffered in the course of replication. We have also known for many years that genomic instability--including mutations, chromosomal rearrangements, and aneuploidy--is a hallmark of cancer cells. Although genomic instability has many contributing causes, including faulty replication, there are many indications that recombination, faulty or not, contributes to genome instability and cancer as well. The (Nas colloquium) Links Between Recombination and Replication: Vital Roles of Recombination was convened to broaden awareness of this evolving area of research. Papers generated by this colloquium are published here. To encourage the desired interactions of specialists, we invited some contributions that deal only with recombination or replication in addition to contributions on the central thesis of functional links between recombination and replication. To aid the nonspecialist and specialist alike, we open the set of papers with a historical overview by Michael Cox and we close the set with a commentary on the meeting and the field by Andrei Kuzminov.
DNA Replication, second edition, a classic of modernscience, is now back in print in a paperback edition. Kornberg and Baker'sinsightful coverage of DNA replication and related cellular processes have madethis the standard reference in the field.