BCO-DMO | ERDDAP - bcodmo_dataset_897359_v1

Row Type	Variable Name	Attribute Name	Data Type	Value
attribute	NC_GLOBAL	cdm_data_type	String	Other
attribute	NC_GLOBAL	Conventions	String	COARDS, CF-1.6, ACDD-1.3
attribute	NC_GLOBAL	creator_email	String	info at bco-dmo.org
attribute	NC_GLOBAL	creator_name	String	BCO-DMO
attribute	NC_GLOBAL	creator_url	String	https://www.bco-dmo.org/
attribute	NC_GLOBAL	doi	String	10.26008/1912/bco-dmo.897359.1
attribute	NC_GLOBAL	infoUrl	String	https://www.bco-dmo.org/dataset/897359
attribute	NC_GLOBAL	institution	String	BCO-DMO
attribute	NC_GLOBAL	license	String	The data may be used and redistributed for free but is not intended\nfor legal use, since it may contain inaccuracies. Neither the data\nContributor, ERD, NOAA, nor the United States Government, nor any\nof their employees or contractors, makes any warranty, express or\nimplied, including warranties of merchantability and fitness for a\nparticular purpose, or assumes any legal liability for the accuracy,\ncompleteness, or usefulness, of this information.
attribute	NC_GLOBAL	sourceUrl	String	(local files)
attribute	NC_GLOBAL	summary	String	Dissolved organic phosphorus (DOP) hydrolysis rates from marine bacterium Ruegeria pomeroyi laboratory cultures.\n\nThese data were collected as part of a study of \"Dissolved organic phosphorus utilization by the marine bacterium Ruegeria pomeroyi DSS-3 reveals chain length-dependent polyphosphate degradation\" (Adams et al., 2022).\n\nStudy abstract:\nDissolved organic phosphorus (DOP) is a critical nutritional resource for marine microbial communities. However, the relative bioavailability of different types of DOP, such as phosphomonoesters (P-O-C) and phosphoanhydrides (P-O-P), is poorly understood. Here we assess the utilization of these P sources by a representative bacterial copiotroph, Ruegeria pomeroyi DSS-3. All DOP sources supported equivalent growth by R. pomeroyi, and all DOP hydrolysis rates were upregulated under phosphorus depletion (-P). A long-chain polyphosphate (45polyP) showed the lowest hydrolysis rate of all DOP substrates tested, including tripolyphosphate (3polyP). Yet the upregulation of 45polyP hydrolysis under -P was greater than any other substrate analyzed. Proteomics revealed three common P acquisition enzymes potentially involved in polyphosphate utilization, including two alkaline phosphatases, PhoD and PhoX, and one 5'-nucleotidase (5'-NT). Results from DOP substrate competition experiments show that these enzymes likely have broad substrate specificities, including chain length-dependent reactivity toward polyphosphate. These results confirm that DOP, including polyP, are bioavailable nutritional P sources for R. pomeroyi, and possibly other marine heterotrophic bacteria. Furthermore, the chain-length dependent mechanisms, rates and regulation of polyP hydrolysis suggest that these processes may influence the composition of DOP and the overall recycling of nutrients within marine dissolved organic matter.
attribute	NC_GLOBAL	title	String	[Ruegeria pomeroyi DOP hydrolysis rates] - Dissolved organic phosphorus (DOP) hydrolysis rates from Ruegeria pomeroyi laboratory cultures (Collaborative Research: Assessing the role of compound-specific phosphorus hydrolase transformations in the marine phosphorus cycle)
variable	Media_Type		String
attribute	Media_Type	long_name	String	Media_type
attribute	Media_Type	units	String	unitless
variable	Growth_Phase		String
attribute	Growth_Phase	long_name	String	Growth_phase
attribute	Growth_Phase	units	String	unitless
variable	Sample_Type		String
attribute	Sample_Type	long_name	String	Sample_type
attribute	Sample_Type	units	String	unitless
variable	DOP_Substrate		String
attribute	DOP_Substrate	long_name	String	Dop_substrate
attribute	DOP_Substrate	units	String	unitless
variable	Hydrolysis_Rate		float
attribute	Hydrolysis_Rate	actual_range	float	0.0426, 233.72
attribute	Hydrolysis_Rate	long_name	String	Hydrolysis_rate
attribute	Hydrolysis_Rate	units	String	umol Pi L-1 hr-1

Row Type

Variable Name

Attribute Name

Data Type

Value

attribute

NC_GLOBAL

cdm_data_type

String

Other

attribute

NC_GLOBAL

Conventions

String

COARDS, CF-1.6, ACDD-1.3

attribute

NC_GLOBAL

creator_email

String

info at bco-dmo.org

attribute

NC_GLOBAL

creator_name

String

BCO-DMO

attribute

NC_GLOBAL

creator_url

String

https://www.bco-dmo.org/ (external link)

attribute

NC_GLOBAL

doi

String

10.26008/1912/bco-dmo.897359.1

attribute

NC_GLOBAL

infoUrl

String

https://www.bco-dmo.org/dataset/897359 (external link)

attribute

NC_GLOBAL

institution

String

BCO-DMO

attribute

NC_GLOBAL

license

String

The data may be used and redistributed for free but is not intended\nfor legal use, since it may contain inaccuracies. Neither the data\nContributor, ERD, NOAA, nor the United States Government, nor any\nof their employees or contractors, makes any warranty, express or\nimplied, including warranties of merchantability and fitness for a\nparticular purpose, or assumes any legal liability for the accuracy,\ncompleteness, or usefulness, of this information.

attribute

NC_GLOBAL

sourceUrl

String

(local files)

attribute

NC_GLOBAL

summary

String

Dissolved organic phosphorus (DOP) hydrolysis rates from marine bacterium Ruegeria pomeroyi laboratory cultures.\n\nThese data were collected as part of a study of \"Dissolved organic phosphorus utilization by the marine bacterium Ruegeria pomeroyi DSS-3 reveals chain length-dependent polyphosphate degradation\" (Adams et al., 2022).\n\nStudy abstract:\nDissolved organic phosphorus (DOP) is a critical nutritional resource for marine microbial communities. However, the relative bioavailability of different types of DOP, such as phosphomonoesters (P-O-C) and phosphoanhydrides (P-O-P), is poorly understood. Here we assess the utilization of these P sources by a representative bacterial copiotroph, Ruegeria pomeroyi DSS-3. All DOP sources supported equivalent growth by R. pomeroyi, and all DOP hydrolysis rates were upregulated under phosphorus depletion (-P). A long-chain polyphosphate (45polyP) showed the lowest hydrolysis rate of all DOP substrates tested, including tripolyphosphate (3polyP). Yet the upregulation of 45polyP hydrolysis under -P was greater than any other substrate analyzed. Proteomics revealed three common P acquisition enzymes potentially involved in polyphosphate utilization, including two alkaline phosphatases, PhoD and PhoX, and one 5'-nucleotidase (5'-NT). Results from DOP substrate competition experiments show that these enzymes likely have broad substrate specificities, including chain length-dependent reactivity toward polyphosphate. These results confirm that DOP, including polyP, are bioavailable nutritional P sources for R. pomeroyi, and possibly other marine heterotrophic bacteria. Furthermore, the chain-length dependent mechanisms, rates and regulation of polyP hydrolysis suggest that these processes may influence the composition of DOP and the overall recycling of nutrients within marine dissolved organic matter.

attribute

NC_GLOBAL

title

String

[Ruegeria pomeroyi DOP hydrolysis rates] - Dissolved organic phosphorus (DOP) hydrolysis rates from Ruegeria pomeroyi laboratory cultures (Collaborative Research: Assessing the role of compound-specific phosphorus hydrolase transformations in the marine phosphorus cycle)

variable

Media_Type

String

attribute

Media_Type

long_name

String

Media_type

attribute

Media_Type

units

String

unitless

variable

Growth_Phase

String

attribute

Growth_Phase

long_name

String

Growth_phase

attribute

Growth_Phase

units

String

unitless

variable

Sample_Type

String

attribute

Sample_Type

long_name

String

Sample_type

attribute

Sample_Type

units

String

unitless

variable

DOP_Substrate

String

attribute

DOP_Substrate

long_name

String

Dop_substrate

attribute

DOP_Substrate

units

String

unitless

variable

Hydrolysis_Rate

float

attribute

Hydrolysis_Rate

actual_range

float

0.0426, 233.72

attribute

Hydrolysis_Rate

long_name

String

Hydrolysis_rate

attribute

Hydrolysis_Rate

units

String

umol Pi L-1 hr-1

ERDDAP, Version 2.22
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