Abstract: In a general aspect, upgradability scores are determined, and remedial security measures are identified in a computing environment. The computing environment is analyzed to identify computing resources that are eligible to receive a cryptographic security upgrade. Attributes of the computing resources are identified based on communicating with the computing resources. A set of rules, that define upgradability scores as a function of computing resource attributes, is obtained. Sets of intermediate output values are generated for the respective computing resources by applying the set of rules to the identified attributes of the respective computing resources. Upgradability scores are generated for the respective computing resources from the set of intermediate output values for the respective computing resource. Remedial security measures are identified for respective subsets of the computing resources based on the upgradability scores for the respective subsets.

Abstract: The present invention refers to method for producing a transgenic plant with increased herbicide tolerance or resistance as compared to a corresponding non-transformed wild type plant, comprising transforming a plant cell or a plant cell nucleus or a plant tissue with a nucleic acid molecule encoding an Alopecurus cytochrome P450 monooxygenase, as well as to the nucleic acid, and plants with increased herbicide tolerance or resistance comprising the nucleic acid of the invention. Furthermore, the present invention refers to methods of controlling weeds at a locus which contains a plant with increased herbicide tolerance or resistance comprising the nucleic acid of the invention.

Abstract: The present invention refers to method for producing a transgenic plant with increased herbicide tolerance or resistance as compared to a corresponding non-transformed wild type plant, comprising transforming a plant cell or a plant cell nucleus or a plant tissue with a nucleic acid molecule encoding an Alopecurus cytochrome P450 monooxygenase, as well as to the nucleic acid, and plants with increased herbicide tolerance or resistance comprising the nucleic acid of the invention. Furthermore, the present invention refers to methods of controlling weeds at a locus which contains a plant with increased herbicide tolerance or resistance comprising the nucleic acid of the invention.

Abstract: The present invention refers to method for producing a transgenic plant with increased herbicide tolerance or resistance as compared to a corresponding non-transformed wild type plant, comprising transforming a plant cell or a plant cell nucleus or a plant tissue with a nucleic acid molecule encoding an Alopecurus cytochrome P450 monooxygenase, as well as to the nucleic acid, and plants with increased herbicide tolerance or resistance comprising the nucleic acid of the invention.

Abstract: This invention relates generally to a method for quantifying the number of occurrences of a specific nucleic acid sequence within a nucleic acid sample in order to circumvent the shortcomings of the methods currently available and to provide reliable quantification of a specific nucleic acid sequence within a nucleic acid sample. The present invention provides a method of assessing an amount of a known target nucleic acid sequence in a sample comprising co-amplifying said target nucleic acid sequence and a known amount of a known control nucleic acid sequence to produce respective target and control amplicons, wherein said control nucleic acid sequence is different than said target nucleic acid sequence; and determining relative amounts of said respective amplicons by determining relative quantities of a primer extension reaction using each of said respective amplicons as a template.

Abstract: The present invention includes nuclear fertility restorer genes, proteins encoded by those genes and transgenic plants and plant cells containing those genes. More particularly, the nuclear fertility restorer genes can be used to restore fertility in cytoplasmic male-sterile plants such as Brassica napus. Preferably, the nuclear fertility restorer genes are used with the Ogura (ogu) CMS system in Brassica napus.

Abstract: This invention relates generally to a method for quantifying the number of occurrences of a specific nucleic acid sequence within a nucleic acid sample in order to circumvent the shortcomings of the methods currently available and to provide reliable quantification of a specific nucleic acid sequence within a nucleic acid sample. The present invention provides a method of assessing an amount of a known target nucleic acid sequence in a sample comprising co-amplifying said target nucleic acid sequence and a known amount of a known control nucleic acid sequence to produce respective target and control amplicons, wherein said control nucleic acid sequence is different than said target nucleic acid sequence; and determining relative amounts of said respective amplicons by determining relative quantities of a primer extension reaction using each of said respective amplicons as a template.

Abstract: The present invention provides compositions and methods for assaying commercially relevant imidazolinone herbicide tolerance conferred by a Brassica napus AHAS1 PM1 mutation and a Brassica napus AHAS3 PM2 mutation in a plant.

Abstract: The present invention includes nuclear fertility restorer genes, proteins encoded by those genes and transgenic plants and plant cells containing those genes. More particularly, the nuclear fertility restorer genes can be used to restore fertility in cytoplasmic male-sterile plants such as Brassica napus. Preferably, the nuclear fertility restorer genes are used with the Ogura (ogu) CMS system in Brassica napus.