Recent
Patents on Biotechnology
ISSN: 1872-2083
Recent Patents on Biotechnology
Volume 2, Number 2, June 2008
Contents
Contributions of Biotechnology to the Production
of Mannitol Pp. 73-78
Kristiina Kiviharju and Antti Nyyssölä
[Abstract]
Optimization of Protein Secretion by Bacillus
subtilis Pp. 79-87
Reindert Nijland and Oscar P. Kuipers
[Abstract]
Membrane Aerated Biofilm Reactors: A Brief Current
Review Pp. 88-93
Tinggang Li, Junxin Liu and Renbi Bai
[Abstract]
Gene Targeting for Chromosome Engineering Applications
in Eukaryotic Cells Pp. 94-106
Leszek A. Lyznik and Virginia Dress
[Abstract]
Citric Acid Production Patent Review
Pp. 107-123
Savas Anastassiadis, Igor G. Morgunov, Svetlana V. Kamzolova
and Tatiana V. Finogenova
[Abstract]
Diagnosis of Pathogens Using DNA Microarray Pp. 124-129
Seung M. Yoo and Sang Y. Lee
[Abstract]
Process Optimization for Biodiesel Production
Pp. 130-143
Veena Singh, Kusum Solanki and Munishwar N. Gupta
[Abstract]
Patent Selections Pp. 144-149
Abstracts
[Back to top]
Contributions of Biotechnology to the Production
of Mannitol
Kristiina Kiviharju and Antti Nyyssölä
Mannitol is a 6-carbon sugar alcohol that has been produced
traditionally by chemical catalysis. Biotechnology has brought
advances to the production in terms of substrate purity, process
equipment requirements and safety. Enzymatic methods have
improved the yields and the use of microbes has brought versatility
to the range of substrates that can be used in the processes.
Some of the microbial processes are already industrially feasible
and could be taken to further use. The most promising production
strategy reported so far has been the utilization of non-growing
cells of heterofermentative lactic acid bacteria for converting
fructose to mannitol. The latest developments in the field
have dealt with the use of recombinant strains in mannitol
production.
[Back to top]
Optimization of Protein Secretion by Bacillus subtilis
Reindert Nijland and Oscar P. Kuipers
The gram-positive bacterium Bacillus subtilis
is widely known for its capacity to produce and secrete large
amounts of industrially relevant proteins, mostly endogenous
enzymes like proteases and lipases. The use of B. subtilis
has many advantages, such as its GRAS status and the easy
and inexpensive culturing methods that can result in very
high cell densities. Over the years many patents have been
filed regarding the optimization of protein secretion by B.
subtilis. For almost every step in the production and
secretion process, from promoter optimization to deletion
of extracellular proteases, patents have been claimed. An
overview of the current literature and patents on these subjects
is given. We will discuss recent patents regarding the optimization
of protein overexpression and secretion in B. subtilis.
A patent claiming modification of B. subtilis SecA will be
discussed in more detail. Another recent patent claims a positive
effect of heterologous protein secretion upon reduced expression
of the yusZ and/or yusX genes, encoding
putative oligopeptidases. Improvements are being made continuously,
although many depend on the character of the specific protein
under study.
[Back to top]
Membrane Aerated Biofilm Reactors: A Brief Current Review
Tinggang Li, Junxin Liu and Renbi Bai
Membrane aerated biofilm reactors (MABRs) represent a
relatively new biotreatment technology. In a MABR, biofilm
is grown on a gas-permeable membrane (often a hollow fiber
membrane). Soluble organic compounds in the liquid are supplied
to the biofilm from the biofilm-liquid interface whereas oxygen
supply to the biofilm is from the biofilm-membrane interface
(by oxygen diffusing through the membrane). MABRs can achieve
bubble-less aeration and high oxygen utilization efficiency
(up to 100%) and the biofilm can be stratified into aerobic/anoxic/anaerobic
zones to simultaneously achieve removal of carbonaceous organic
pollutants as well as nitrification and denitrification (if
needed) in a single biofilm. This article briefly reviews
the MABR process, including the characteristics, membrane
materials, modular design, operation parameters and the potential
applications, from relevant recent patents and literature.
[Back to top]
Gene Targeting for Chromosome Engineering Applications in
Eukaryotic Cells
Leszek A. Lyznik and Virginia Dress
As biotechnology advances, there is an increasing need
to develop new technologies that may assist in more precise
genetic engineering manipulations. Whether a placement of
single genes in the proper chromosomal context, stacking a
number of genes in the same chromosomal locus, rearrangement
of existing chromosomal elements, or a global reconfiguration
of the chromosomal structures is contemplated, the new genetic
tools being developed provide technical capabilities to achieve
goals that were only theoretical not long ago. We use examples
of recent patent literature (issued patents and published
patent applications) to illustrate trends in this fast advancing
area of genetic technology. If one wants to engage in the
development and utilization of such technologies, the complexity
of genetic manipulations requires a careful evaluation and
navigation across the legal/patent landscape of chromosomal
modification/remodeling. While this review is mostly focused
on the basic laboratory tools of chromosomal manipulations,
their specific applications for biomedical, pharmaceutical,
or agricultural purposes may deserve an additional compilation.
[Back to top]
Citric Acid Production Patent Review
Savas Anastassiadis, Igor G. Morgunov, Svetlana V. Kamzolova
and Tatiana V. Finogenova
Current Review article summarizes the developments in
citric acid production technologies in East and West last
100 years. Citric acid is commercially produced by large scale
fermentation mostly using selected fungal or yeast strains
in aerobe bioreactors and still remains one of the runners
in industrial production of biotechnological bulk metabolites
obtained by microbial fermentation since about 100 years,
reflecting the historical development of modern biotechnology
and fermentation process technology in East and West. Citric
acid fermentation was first found as a fungal product in cultures
of Penicillium glaucum on sugar medium by Wehmer
in 1893 [1]. Citric acid is an important multifunctional organic
acid with a broad range of versatile uses in household and
industrial applications that has been produced industrially
since the beginning of 20th
century. There is a great worldwide demand for citric acid
consumption due to its low toxicity, mainly being used as
acidulant in pharmaceutical and food industries. Global citric
acid production has reached 1.4 million tones, increasing
annually at 3.5-4.0% in demand and consumption. Citric acid
production by fungal submerged fermentation is still dominating,
however new perspectives like solid-state processes or continuous
yeast processes can be attractive for producers to stand in
today’s strong competition in industry. Further perspectives
aiming in the improvement of citric acid production are the
improvement of citric acid producing strains by classical
and modern mutagenesis and selection as well as downstream
processes. Many inexpensive by-products and residues of the
agro-industry (e.g. molasses, glycerin etc.) can be economically
utilized as substrates in the production of citric acid, especially
in solid-state fermentation, enormously reducing production
costs and minimizing environmental problems. Alternatively,
continuous processes utilizing yeasts which reach 200-250
g / l citric acid can stand in today’s strong competition
in citric acid industry and replace the traditional discontinuous
fungi processes.
[Back to top]
Diagnosis of Pathogens Using DNA Microarray
Seung M. Yoo and Sang Y. Lee
DNA microarray technology offers a new way to clinical diagnostics
involving biomarker discovery and disease diagnosis. DNA microarray
can be used for diagnosis of pathogens by analyzing hybridization
patterns between capture probes and nucleic acids isolated
from clinical samples. It allows more rapid, accurate, and
cost-effective detection of pathogens compared with traditional
approaches of cultivation- or immuno-assays. As infectious
diseases are posing more serious threats to public health
care, development of a rapid and accurate method for pathogen
detection is critical to the proper treatment of infected
patients at the earliest time. Here we review recent patents
on the use of DNA microarray for diagnosing pathogens.
[Back to top]
Process Optimization for Biodiesel Production
Veena Singh, Kusum Solanki and Munishwar N. Gupta
Biodiesel is an alkyl ester of long chain fatty acids
and is considered to leave smaller footprint on the environment.
It is produced by transesterification of a fat/oil with a
short chain primary alcohol like methanol or ethanol. The
three routes to its preparation are: alkali catalyzed, acid
catalyzed and lipase-catalyzed transesterification.
This review summarizes the key patents filed over the last
few decades. The chemistry used in these patents is one of
the three routes mentioned above. In few patents, heterogeneous
catalysts have been used for catalyzing the transesterification
process. The innovations mostly concern fine-tuning of the
reaction conditions, plant design to improve logistics and
use of glycerol produced as a by-product during biodiesel
production.
There is a concern that biofuels like biodiesel cut into resources
like land meant for food crop production. Life cycle studies
also create doubt about there being energy efficient fuels.
Judicious choices that would differ with different regions
are recommended. For the next few decades till better alternatives
like hydrogen become viable, biodiesel would continue to be
an important “alternative fuel”.
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