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Synbio Technologies to attend PEGS 2017

Monmouth Junction, New Jersey – April, 2017 – Synbio Technologies will attend the 13th annual Essential Protein Engineering Summit (PEGS), May 1-5, 2017, at the Seaport World Trade Center in Boston, Massachusetts.
Synbio Technologies to attend PEGS

Visit our booth, # 112, to learn more about Synbio Technologies’ advanced “GPS” (Genotype-Phenotype-Synotype) platforms and comprehensive biological solutions. Our scientific capabilities encompass areas such as: DNA engineering, DNA synthesis, genome synthesis, pathway synthesis, synthetic biology, pharmacogenomics, microbiology, translational biology and the various applications of synthetic biology.

We will be presenting our latest technological advances for the following services:

Syno^®3.0 Gene Synthesis – starting at $0.09/bp
Metabolic Pathway Design and Synthesis
Syno^®DNA Library Design and Synthesis
CRISPR-Cas9 Gene/Genome Editing
Protein Expression and Purification
Syno^®Ab and GenoTM Ab Antibody Discovery Platforms

About Synbio Technologies：

Synbio Technologies is a DNA technology company, focusing on the next generation DNA synthesis and its applications. We have built up the first integrated GPS (Genotype, Phenotype and Synotype) system aimed to a quick and easy translation or reverse translation between “Genotype” and “Phenotype” by using our proprietary “Synotype” platform. The company’s scientific capabilities encompass areas such as DNA engineering, DNA synthesis, genome synthesis, pathway synthesis, synthetic biology, pharmacogenomics, microbiology, translational biology and the applications of synthetic biology. Synbio Technologies’ team has a proven track record regarding translating scientific breakthroughs into cost effective biological solution.

Contact：
1 Deer Park Drive, Suite L-1
Monmouth Junction
NJ, 08852
USA
Tel: +1 732-230-3003
Fax: +1 609 228 5911

The Methods of PCR Cloning

PCR Cloning is a technique used to amplify a specific region of DNA strand, and is used in almost every molecular biology lab in the world. PCR can be used on almost any DNA region, provided that suitable primers can be made. Synbio Tech provides one-stop PCR cloning services, including primer design.

PCR Primer Design Procedure

Acquisition of DNA sequence: For amplification of known DNA sequences, tried-and-tested primers can be found on the NCBI website. For unknown DNA sequences containing conserved sequence(s) from related species, primers should be designed according to the DNA or RNA of the conserved sequence(s).
PCR primer design: Many commercial software products and online tools are used to design primers. Primer Premier 5.0, the most popular primer design software, is both powerful and convenient to use. It can also contrast and comprehensively assess the best choice of primer according to their specificity.
Validation of PCR amplification: Once primer synthesis finishes, the accuracy of the primer can be predicted after gel electrophoresis of PCR product.

Notes About PCR Primer Design

The length of primer should be around 18-24bp. If the primer is too short, the primer specificity will be too low; if the primer is too long, it may cause base pair mismatches and may reduce the PCR amplification efficiency.
The GC% of the primer will affect the denaturation temperature (Tm). Tm should be around 55-80℃ and the annealing temperature difference between the upstream and downstream primers should be within 10℃. Usually, the GC% of primer should be between 40%-60% ,and the GC% difference between the upstream and downstream primers should be within 20% of each other in order to enhance primer specificity.
Repetitive structures or high similarity with the template sequence should be avoided as both may lead to possible base pair mismatches.
Secondary structure of primers may inhibit the PCR reaction, and should be avoided.

Synbio Technologies provide one-stop PCR cloning services, including primer design. Our Syno^®2.0 platform can clone the target gene to any specific point on a provided vector without relying on restriction enzyme sites, to best satisfy the cloning requirements of each client.

PCR Techniques in Biology

Polymerase chain reaction, generally known as PCR and also referred to as in vitro DNA amplification, is one of the most widely used techniques in biology labs across the world.

Traditional DNA amplification method

Traditional DNA amplification involves the construction of a vector containing the target gene, followed by the transfer of the vectors into cells to amplify the target gene and then screening by probe. The process includes enzyme digestion, connection, transformation, culture, and probe hybridization. Although there are no technical difficulties for the traditional method, the complicated operation and long cycle length make it suboptimal as a way to amplify DNA. PCR is faster, more efficient, and cheaper, and has many advantages over traditional DNA amplification.

Advantage of PCR cloning

PCR was first theorized by Kary Mullis in 1983 and was later invented in 1985. PCR can amplify traces of DNA and generate millions of copies of a particular DNA sequence. Because of its high sensitivity, specificity, and yield, along with its reproducibility, speed, and convenience, PCR is now widely used in microbiology, medical science, agriculture, and many other fields. PCR has greatly simplified the process of molecular cloning, enabling researchers to much more easily analyze and identify genes of interest.

Basic principles of PCR cloning

At a temperature of 95℃, DNA denatures and yields single-stranded DNA molecules. The primer then binds to a complementary part of the DNA template. The temperature is then lowered to the optimum activity temperature, which is usually around 72℃. This activates DNA polymerase, which synthesizes a new DNA strand complementary to the DNA template in the 5’ to 3’ direction. The DNA template, primers, and polymerase are then thermocycled through denaturation, annealing, and extension steps, allowing DNA polymerase to replicate a target region of DNA by millions of times or more.

PCR has become an essential part of biology labs around the world, and is widely applied to gene cloning, genetic recombination, DNA sequence analysis, and gene quantification. PCR Cloning is also used in cancer gene detection and early diagnosis of hereditary diseases.

Our Syno^®2.0 platform can clone any target gene to any specific point on required vectors
without depending on restriction enzyme sites. We promise both accurate and speedy delivery of any client’s cloning requests.

Applying Moore’s Law to Gene Synthesis

Moore’s law suggests that the number of transistors on integrated circuits doubles about every two years while the cost halves.

The law applies to DNA sequencing (DNA “reading”) since 2000 and the force of the law drives exponential growth in sequencing industry that is forecasted to grow to $6.6 billion over the year 2016.

The force driven the law in DNA synthesizing (DNA “writing”) has not been emerging. For decades, Synbio Technologies’ team focuses on DNA synthesis technologies and commits to explore a driving force linked to Moore’s law in synthesis industry.

Synbio technologies’ cutting edge Syno® 3.0 platform offers DNA synthesis starts at $0.09/bp.
Syno® 2.0 platform gene synthesis promotion: starting from $0.19/bp.
Patent pending DNA library design and synthesis provide a powerful tool to build up the “high performing” molecules.

Gene Synthesis Related Services

How to order

Get a quote: online request submission form.

Submit gene/protein sequence: Gene synthesis online inquiry.

Or please email your detailed sequences and requirements directly to: service@synbio-tech.com, Tel.: +1 732-230-3003. Project managers of Synbio Tech. will contact you within 24 hours after we receive your request.

Codon Usage Bias

The genetic information in DNA is transcribed into mRNA then translated into protein, in which codons played important roles during the process. Total 64 combinations of nucleotide triplet (codon) encode all 22 amino acids. Each amino acid corresponds to at least one codon, e.g. methionine and tryptophan. In other cases, amino acids are encoded by 2 to 6 different codons. The codons encode the same amino acid are referred as synonymous codons. The frequency of synonymous codon usage varies widely among different organisms, and these differences have important implications for the regulation of protein expression. In the process of protein synthesis, a particular species tends to use a set of specific codons, which are called optimal codons. This phenomenon is also known as codon usage bias. So the use of different species in the codon usage bias, optimizing the use of codons can increase the protein expression.

Codon usage bias and protein

At the same time, accurate polypeptide elongation could minimize the energy waste caused by translation errors. Therefore, a codon with optimal translation speed and high fidelity will result high translation efficiency and an increased protein expression. The combination of codons and translation efficiency are not only contributing to the codon usage bias of the whole genome, but also the distribution of codons with different translation efficiency in different regions. The codon usage bias in different regions can regulate genes expression at different stages, such as affecting the mRNA expression during transcription, the speed and accuracy of translation, and the folding of polypeptide.

In the heterologous protein expression system, selecting the codon combinations that control the speed of translation is essential to avoid formation of inclusion bodies due to high expression or not obtaining any protein at all. Thus a well-tuned system for controlled gene expression is the key component for protein production in industrial and scientific research.

Synbio Tech proprietary NG^TMCodon Optimization software can intelligently optimize codons based on different expression systems and effectively improve the protein expression in order to meet the needs of scientific research and industrial production.

Synbio Technologies’ Codon Optimization Strategy

Translation is the last step in protein synthesis that results in stable proteins from DNA replication, mRNA transcription and modification in cells. Codon optimization aims to increase the yield of protein expression in different organisms by rebalancing usage of synonymous codons. High quality protein has a wide range of applications, including study of protein structure and function, biological research, clinical medicine.

Higher protein yield in turn can be a valuable feature in a wide range of applications, including…

Codon usage bias

There are 64 codons in total, 61 codons encode 20 amino acids and the remaining 3 are stop codons. Redundant codons exist for most amino acids; multiple different codons encode the same amino acid. In general, the expression of heterologous proteins is negatively correlated with the occurrences of rare codons. In simpler terms, when the codon usage of a target protein in its native organism differs significantly from the average codon usage of the expression host, this could cause problems during expression. Therefore, an effective solution is to replace rare codons in the original sequences with major codons that are preferred in the host.

The secondary structure of mRNA

Translation refers to the conversion of nucleic acid sequences into amino acid sequences, and is greatly affected by complex secondary structures in mRNA. The translation of codons in the non-structural part of the α-helix is the rate-determing step in the translational process. Identifying the hairpin structure in an mRNA can lead to significant optimizations of translational efficiency for that mRNA.

Changing regulatory elements and restriction sites

The process of optimizing protein expression is affected by many factors: not only basic DNA transcription and translation, but also a series of regulatory elements. By incorporating signal peptides, tags, other regulatory elements, or appropriate restriction sites during gene synthesis, expression of synthetic genes in heterologous host organisms can be significantly improved.

Synbio Tech NG^TMCodon Optimization software can intelligently optimize codon usage to effectively improve protein expression, in order to better meet the needs of scientific research and industrial production.

Synbio Technologies’ NG^TMCodon Optimization Software

Synbio Technologies’ proprietary NG^TMCodon optimization software provides customers with free codon optimization services bundled with gene synthesis. Our NG^TM Codon optimization software optimizes gene sequences based on different expression systems to maximize protein expression.

NG^TMCodon optimization software advantages：

Elimination of codon usage bias:

Codon usage bias refers to the differences in frequency of synonymous codons in coding DNA, and exists in a wide variety of organisms. The most frequently used codon is called the optimal codon, and lower frequency codons are called rare codons. Synbio Technologies’ proprietary codon optimization software, NG^TMCodon optimizes the usage of both the optimal codon and the rare codons to achieve superior protein expression.

Fine-tuning secondary structure of mRNA

The secondary structure of mRNAs play an active role in the translation process. The complexity and stability of mRNA secondary structure both greatly affect the smoothness of the translation process, in particular, secondary structure near the ribosome binding site (RBS) is crucial. NG^TMCodon can effectively identify and minimize hairpin structures in mRNA, effectively optimize the original sequence, and generate significant improvements in protein expression.

Removal of negative cis-acting elements and restriction sites

NG^TMCodon was designed to eliminate multiple obstacles during transcription and translation by minimizing negative cis-acting elements that interfere with transcription and translation.

Case study：Targeting protein was reproducibly expressed in E. coli after codon optimization by NG^TMCodon.

NG^TMCodon improves codon usage efficiency

Four Steps of Subcloning Technology Protocol

Subcloning refers to the technique of re-cloning a DNA fragment from one vector to another, so that we can more easily perform analysis, transformation, and recombination of the target gene(s). Subcloning is an important tool in any molecular biologist’s toolkit, helping to elucidate the function of a target gene and to easily analyze its phenotype. There are four steps in the subcloning process: obtain the target fragment, connect enzyme vector and target fragment, transform in host cell, identify and screen.

Subcloning Technology Protocol- obtain the target fragment

Find the target fragment in a gene library
The cDNA sequence was reverse transcribed with mRNA as a template through PCR, so we can obtain the target fragment from the cDNA library
Cut the DNA into many fragments with restriction enzymes and introduce into cells; we can screen for cells containing the target gene(s)
Synthesize the gene sequences in vitro

Subcloning Technology Protocol- connect enzyme vector and target fragment

Choose an appropriate restriction enzyme to cleave the target fragment from the vector. Cleavage in this way usually generates symmetrical cohesive ends, non-symmetric cohesive ends, or blunt ends. For subcloning, non-symmetric cohesive ends are preferred.

Subcloning Technology Protocol- transform into host cell

The two most common methods of transforming the target fragment into cells are transformation / transfection and transduction. In the first method, a recombinant plasmid or phage is simply transformed into a treated host cell; in the second, a host cell is transducted with a virus harboring exogenous DNA. In general, transduction is more efficient than transformation.

Subcloning Technology Protocol-identify & screen

Vectors with recognizable genetic markers can be used to help distinguish and separate cells transformed with recombinant DNA. For example, color can be used as such a marker, as the color of a colony may change in some vectors with exogenous genes. Other effective and widely used screening methods also exist, such as screening with drugs or with selective media.

With our Syno^®2.0 gene synthesis platform and experienced technical team, Synbio Technologies provides one-stop subcloning services including target gene synthesis, vector construction and transformation, identification, and screening.

Synbio Technologies’ PCR cloning and Subcloning Technology

PCR cloning and subcloning technology, first developed in the 1970s, is now a staple in every molecular biology lab in the world. Cloning allows researchers to much more easily understand gene function at a deeper level, and greatly facilitates gene editing. PCR cloning and subcloning technology is not only revolutionary for the field of biology, but has profound implications on fields like agriculture, industry, and medicine as well.

PCR cloning technology

PCR cloning technology is similar to natural DNA replication, and contains three basic reaction steps: modification-annealing-extension. We can obtain a desired target gene sequence with appropriate primer design. PCR can then be used to amplify this gene sequence, preparing it for use in cloning.

Subcloning technology

In molecular cloning, target DNA is assembled into a vector plasmid through restriction enzymes and screening. In subcloning, a gene of interest is transferred from one vector to another. Both processes consist of several key steps, such as screening of the target fragment, cloning vector preparation, transformation/transduction of the product into cells, and screening for cells containing recombinant plasmids.

Both PCR cloning and subcloning technology can insert a target gene into a plasmid of choice in vitro through recombinant technology. The main forms of target gene transfer into a plasmid are transformation and transduction. This allows researchers to have an enormous amount of customization available to them when trying to study a gene of interest, making cloning and sub-cloning two extremely powerful tools in a molecular biologist’s arsenal.

With our proprietary Syno^®2.0 gene synthesis platform, Synbio Technologies can provide one-step services for gene synthesis, vector construction, PCR cloning, and subcloning. Customers only need to offer the sequence information, and we can help design amplification primers and clone the PCR products to the specific sites of the new plasmid. We also provide sequencing services in order to confirm that the correct product was accurately synthesized.

Genome Editing Technology vs Transgenic Technology

Genome editing technology

Genome editing technology enables genetic engineering where DNA is replaced, deleted or inserted in the genome of a living organism, and the emergence of CRISPR-Cas9 system has further facilitated the realization of precise genetic modifications. Gene mapping and precise genetic modifications by inducing targeted DNA double-strand breaks opened up new avenues for the application of genome editing technology in drug development, gene therapy, agricultural breeding, environmental protection and endangered animal rescue.

Transgenic technology

Transgenics describes the process of introducing foreign DNA into a host organism’s genome. The foreign DNA, or “transgene,” that is transferred to the recipient can be from other individuals of the same species, from different species or even from artificially synthesized DNA. The foreign DNA was incorporated into the host genome by either homologous recombination or non-homologous recombination, and the following trait selection on a population allows cultivar development within a species to create offspring with desirable traits.

The difference between genome editing technology and transgenic technology

Both Genome editing technology and transgenic techniques can alter the genome of an organism so that the desirable trait can be inherited, but there is a big difference between the two. Genome editing is the manipulation of the genome of the organism itself by knocking out or replacing targeted gene which resulting in individuals with intentionally selected and desired traits, while transgenic technology can only introduce biologically nonexisting foreign genes to the original organisms in order to tailor the species with new traits. Therefore, the use of gene editing technology, can be fast, accurate and without the introduction of exogenous DNA fragments in the case of the organism genome transformation. The US Department of Agriculture (USDA) has shown lenient to genetically modified crops comparing to its controversial transgenic sibling. The decision means that the genetically modified crops can be cultivated and sold without passing through the agency’s regulatory process. The green light from USDA allows the flourish of valuable and disease-resistant crops while bypassing the use of controversial transgenic technologies.

The Comparison Between Three Generation Genome Editing Technologies

Genome editing refers to a type of genetic engineering in which DNA is replaced, deleted or inserted in the genome of a living organism using engineered nucleases. These engineered nucleases enable efficient and precise genetic modifications by inducing targeted DNA double-strand breaks (DSBs) that stimulate the cellular DNA repair mechanisms, There are currently three families of engineered nucleases being used, zinc finger nucleases (ZFNs), transcription activator-like effector-based nucleases (TALEN), and the CRISPR-Cas system.

The mechanism of ZFN and TALEN system

ZFN and TALENs undergo similar molecular mechanisms for executing genome editing. ZFN and TALENs are both engineered nucleases composed of a DNA binding domain that recognize a specific nucleotide triplet based on the residues in their helix and a FokI nuclease motif that have a strong catalytic cleavage capability for specific nucleotides. The FokI domains must dimerize for activity, thus increasing target specificity by ensuring that two proximal DNA-binding events must occur to achieve a double-strand break (DSBs). These chimeric nucleases enable efficient and precise genetic modifications by inducing targeted DNA DSBs that stimulate the cellular DNA repair mechanisms, including error-prone non-homologous end joining (NHEJ) and homology-directed repair (HDR).

The mechanism of CRISPR system

CRISPR is a ubiquitous family of clustered repetitive DNA elements present in 90% of Archaea and 40% of sequenced Bacteria. The CRISPR system was first identified as an adaptive defensive mechanism that confers resistance to foreign genetic elements. Later on, CRISPR-Cas system was engineered into a versatile gene-editing tool enabling manipulation of protospacer adjacent motif (PAM) downstream DNA. CRISPR-Cas9 genome editing system consists of two components: a “guide” RNA (gRNA) and a non-specific CRISPR-associated endonuclease (Cas9). The Cas9 protein is an endonuclease that uses guide RNA molecule (gRNA) to form base pairs with DNA target sequences, enabling Cas9 to introduce a site-specific DSB in the DNA. The CRISPR-Cas9 system offers unprecedented advantages over the ZFN and TALEN strategies. Due to its simplicity and efficiency, CRISPR-Cas9 system has quickly become the go-to genome engineering tool for animal model construction, drug development, gene therapy, agricultural breeding and many other applications.

Based on our knowledge and years of experience in DNA technology, Synbio Technologies has developed CRISPR-Cas9 gene/genome editing platform. We offer a one-stop solution for CRISPR-Cas9 projects to achieve high genome editing efficiency, including CRISPR-Cas9 sgRNA design, CRISPR-Cas9 sgRNA library design and genome editing.

The Applications of Genome Editing Technology

Genome editing technology enables manipulations at genome level where DNA is replaced, deleted or inserted in a living organism. Classic genome editing approaches depend on homology-directed repair and the totipotency of stem cells to facilitate the modification of the individual gene. The Nobel Prize in Physiology or Medicine 2007 was awarded to the discoveries of principles for introducing specific gene modifications in mice by the use of embryonic stem cells. Because the traditional HDR approach has disadvantages of low efficiency, high technical requirements and high cost, which seriously restricted its applications in large-scale genomic manipulation research. In 2013 the discovery of the type II CRISPR-Cas9 system has promoted the development of precise genetic modifications. This new RNA-mediated DNA editing approach opens up new avenues for the application of genome editing technology in Animal model construction, genetic disease treatment and agricultural breeding.

Genome editing technology——Generation of Animal models

CRISPR-Cas9 system performs precise targeting and editing a specific DNA sequence of interest via a programmable mechanism, and provides a versatile approach to establish transgenic animal models. While mouse models have been widely used, the CRISPR-Cas9 gene-editing approach has been established in many other animal models, including worm, rat, rabbit, pig and monkey. New mouse models can be generated with CRISPR-Cas9 by injecting Cas9 mRNA and guide RNAs (sgRNA) directly into mouse embryos to generate precise genomic edits into specific loci with an efficiency of 100%. CRISPR-Cas9 mediated targeting and editing has facilitated the generation of knockin and knockout mouse models, dramatically decreases the time and resource consumption comparing to traditional methods.

Genome editing technology——Curing genetic diseases

Although CRISPR-Cas9 has already has been widely used as a research tool, a particularly exciting future direction is the development of CRISPR-Cas9 as a therapeutic technology for treating genetic disorders. Researchers at Chinese Academy of Sciences reported successful correction of disease-causing mutations in cataract mouse models via the CRISPR-Cas9 system. Upon injection of CRISPR-Cas9 into zygotes, 1/3 genetic defect in the cataract mouse model could be corrected at the organism level and more importantly the corrected trait was successfully transmitted to the next generation through the germline.

Genome editing technology——Agricultural breeding

The CRISPR-Cas9 technology opens up exciting possibilities for creating crop varieties with desirable traits without introducing foreign DNA. Precision breeding crops with desirable traits, such as disease resistance and drought tolerance not only help reduce pesticide, fertilizer and water usage, but also improve food quality and safety. Researchers at Penn State University created mushrooms with reduced production of a specific enzyme that causes mushrooms to blemishes caused by handling or mechanical harvesting. It becomes the first CRISPR-edited organism to receive a green light from the US government, means that the mushroom can be cultivated and sold without passing through the agency’s regulatory process.

CRISPR-Cas9 is an emerging technology that enables precise genome modification without introducing foreign genes. This transformative tool holds great promises to revolutionize biological research and expand our ability correcting the genetic causes behind many diseases.

Synbio Technologies establish the CRISPR-Cas9 gene/genome editing platform which can offer a one-stop solution for CRISPR-Cas9 projects. We can offer the services including: CRISPR-Cas9 sgRNA design, CRISPR-Cas9 sgRNA library design and genome editing.

A Brief Introduction of Molecular Biology Techniques

Molecular biology studies the morphology, structural features, biological relevance and regulatory mechanism of biological macromolecules including nucleic acid, protein and others. Molecular biology truly uncovered the mysteries of the biological world from the molecular level; it signaled the transition from passive adaption from nature to actively restructuring and reengineering the nature.

The main research contents of molecular biology span a broad spectrum: applications of DNA recombinant technology (also known as genetic engineering) in genetic engineered drugs; transgenic plants and somatic cell nuclear transfer; gene expression and regulation; structure-function relationship of biological macromolecules; functional genomics and bioinformatics studies.

Molecular biology is the cornerstone of current life sciences and medicine-related disciplines. Molecular biology techniques are the most commonly used tools in life science, however the viability and reliability of experiment result are dependence of many factors, including experience and expertise.

Empowered by Syno^®1.0 and Syno^®2.0 platforms, Synbio Technologies provides comprehensive and accurate molecular biology service for worldwide customers, ranging from DNA cloning, site-directed mutagenesis, vector construction, protein expression, gene/genome sequencing, gene synthesis technology and many other services.

The Wide Applications of Molecular Biology

Molecular biology clarifies regularities of cell and receals the essence of life.Molecular biology technologies have been widely adapted for recombinant protein production, genetic modification of organisms, gene therapy, environmental protection, etc.

Production of recombinant proteins

Recombinant Insulin production

For very long time, the insulin that was used to treat diabetic patients is solely purified from bovine or porcine pancreas. 100kg pancreas can only extract 4-5g of insulin. The development in the field of genetic engineering introduced chemically synthesized insulin cDNA in E.coli and allowed insulin production in microorganisms, yielding 100g insulin from every 2000L microorganism’s culture. The massive industrial scale production of insulin not only solves the yield problem but also drives its price down by 30% -50%.

Genetic engineering drugs

Genetic engineering is used to mass-produce interferon, artificial blood, interleukin, hepatitis B vaccine and many other drugs which played a huge role of lifting the human suffering, improving human health.Genetic engineering drugs has greatly been embraced by man to improve on his well-being.

Genetically modified animal

For certain protein drugs that require complex modifications or are needed in large supply, production in transgenic animals seems most efficient. The current strategy to achieve these objectives is to couple the DNA for the protein drug with a DNA signal directing production in the mammary gland.

Herbicide resistant crops

Herbicide resistant crops are genetically modified to tolerate broad-spectrum herbicides, which kill the surrounding flora, but leave the cultivated crop intact.

Genetically modified microorganism

Microorganisms are most commonly used in genetic engineering due to their inexpensive nature. Cheese production requires the use of a protein called chymosin which is a proteolitic enzyme usually obtained from calf stomachs. Production of chymosin in genetically engineered microorganism provides an alternative way of producing cheese that does not require the sacrifice of large amount of animals. Moreover, microorganism production of recombinant chymosin offers an easy way of increasing the production of chymosin compared to the amount that can be obtained from young calves.

Gene therapy

Gene therapy is a technique to treat genetic diseases by introducing foreign DNA which usually contains a functioning gene to correct the effects of a disease-causing mutation.

Environmental protection

The genetically engineered organisms can be used as bioindicators to readily reflecting pollution level on a habitat, community, or ecosystem. Moreover, these bioindicators are engineered to resist pollutant-leaded mortality and potentially has the capability in bioremediation of toxic chemicals.

Applications of Molecular Biology Techniques in Environmental Microbiology Research

Advances in molecular biology and genetic engineering technology, microbial genetic manipulations have promoted the application of microorganisms in in ecological and environmental research. Genetically engineered microorganisms are being developed and assessed for their beneficial uses in environmental monitoring, toxic chemicals pollution control and genetically engineered microorganisms.

Hybridization Probe

The oligonucleotide probes can hybridize to DNA or RNA whose base sequence allows probe–target base pairing due to complementarity between the probe and target to analyze the presence of nucleotide sequences (the DNA target) that are complementary to the sequence in the probe.

Due to the stringent specificity and high sensitivity of nucleic acid hybridization, hybridization probes are used on a broad level in microbial ecology, such as microbial detection, qualitative and quantitative analysis of microbial, distribution, abundance and adaptability of microbial.

PCR Based Technologies

The polymerase chain reaction (PCR) is a technique used in molecular biology to amplify DNA template, generating thousands to millions of copies of a particular DNA sequence in vitro. This technique can be used to analyze mRNA expression profile among different growth stages.

Electrophoresis

The interaction between DNA double helix are disrupted during denaturing gradient gel electrophoresis(DGGE)， temperature gradient gel electrophoresis(TGGE) and other special forms of electrophoresis, thus the DNA fragments consist of different sequences can be separated on acrylamide gel with superior resolution.

Genetic Engineering

New recombinant DNA may be generated by first isolation and amplification the genetic material of interest using molecular cloning methods, then the chimera DNA sequence or artificially synthesized DNA maybe inserted into the host organism. This technique is essential for the construction of microbes with enhanced biodegradability that may be used in controlling remediation of contaminated environment or fermentation of waste to produce natural gas.

Application of molecular biology technology not only expanded the horizon but also increased the depth of microbial ecology research. The increasing amount of microbe’s genomic data provides new opportunities for understanding the genetic and molecular bases of the degradation genes in various bacteria. The in-depth knowledge of microbes’ genome will make the research more objective and more controllable.