Plant Assessment Form
More Volutaria tubuliflora resources
Volutaria tubuliflora
Synonyms: Amberboa atlantica; Volutaria lippii subsp. tubuliflora
Common Names: desert knapweed; Mediterranean knapweed
Evaluated on: 27-Dec-16
List committee review date: 26/01/2017
Re-evaluation date:
Evaluator(s)
Mona Robison/Science Program Manager
Cal-IPC
916-802-2004
rrobison@cal-ipc.org
List committee members
Elizabeth Brusati
Tim Hyland
Eric Wrubel
Irina Irvine
Holly Forbes
Jutta Burger
Naomi Fraga
Denise Knapp
Chris McDonald
Ron Vanderhoff
John Knapp
General Comments
When V. tubuliflora was first detected in San Diego it was mis-identified as V. canariensis, and is still listed in the Jepson eFlora as V. canariensis. Recenly, Chris McDonald determined that a specimen from Orange County in Newport Bay from 1987 was also V. tubuliflora, moving the introduction date and location to 1987 in Orange County.
The clone of Volutaria that has established at least at the Anza Borrego and Newport colonies are both a naturally uncommon floral morph. This is apparently the same morph that has invaded Chile. However, this morph is uncommon in the native V. tubuliflora range of northern Africa/Mediterranean basin. If all three widely separated California infestations are determined to be the same genotype and also the same as that is in Chile, then it is likely (not certain) that all of the California infestations originated from a single introduction, and dispersed thereafter (Vanderhoff, pers. comm.). I agree the most likely path of Volutaria spread in California is a single introduction and then more local spread out from the first infestation (McDonald, pers. comm.).
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Overall Score ?
Plant scoring matrix
Based on letter scores from Sections 1 through 3 below
| Impact | Invasiveness | Distribution | | |
| A | A B | Any | High | No Alert |
| A | C D | Any | Moderate | Alert |
| B | A B | A B | Moderate | No Alert |
| B | A B | C D | Moderate | Alert |
| B | C D | Any | Limited | No Alert |
| C | A | A B | Moderate | No Alert |
| C | A | C D | Limited | No Alert |
| C | B | A | Moderate | No Alert |
| C | B | B D | Limited | No Alert |
| C | C | Any | Limited | No Alert |
| D | Any | Any | Not Listed | No Alert |
Limited
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Alert Status ?
Plant scoring matrix
Based on letter scores from Sections 1 through 3 below
| Impact | Invasiveness | Distribution | Alert |
| A | A or B | C or D | Alert |
| B | A or B | C or D | Alert |
Alert
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Documentation ?
The total documentation score is the average
of Documentation scores given in Table 2.
| Reviewed Scientific Publication | 4 points |
| Other Published Material | 3 points |
| Observational | 2 points |
| Anecdotal | 1 points |
| Unknown or No Information | 0 points |
2.5 out of 5 |
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Score |
Documentation |
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| 1.1 |
?Impact on abiotic ecosystem processes
Consider the impact on the natural range and variation of abiotic ecosystem processes and system-wide parameters in ways that significantly diminish the ability of native species to survive and reproduce. Alterations that determine the types of communities that can exist in a given area are of greatest concern. Examples of abiotic processes include:
- fire occurrence, frequency, and intensity;
- geomorphological changes such as erosion and sedimentation rates;
- hydrological regimes, including soil water table;
- nutrient and mineral dynamics, including salinity, alkalinity, and pH;
- light availability (e.g. when an aquatic invader covers an entire water body that would otherwise be open).
Select the one letter below that best describes this species' most severe impact on an abiotic ecosystem process:
A. Severe, possibly irreversible, alteration or disruption of an ecosystem process.
B. Moderate alteration of an ecosystem process.
C. Minor alteration of an ecosystem process.
D. Negligible perceived impact on an ecosystem process.
U. Unknown.
|
U. Unknown |
Anecdotal |
Impact?
| Section 1 Scoring Matrix |
|---|
| Q 1.1 | Q 1.2 | Q 1.3 | Q 1.4 | Score |
| A | A | Any | Any | A |
| A | B | A,B | Any | A |
| A | B | C,D,U | Any | B |
| A | C,D,U | Any | Any | B |
| B | A | A | Any | A |
| B | A | B | A | A |
| B | A | B,C | B-D,U | B |
| B | A | C,D,U | A | A |
| B | A | C,D,U | B-D,U | B |
| B | B | A | A | A |
| B | C,D,U | A | A | B |
| B | B-D | A | B-D,U | B |
| B | B-D | B-D,U | Any | B |
| B | D,U | C,D,U | A-B | B |
| B | D,U | C,D,U | C,D,U | C |
| C-D,U | A | A | Any | A |
| C | B | A | Any | B |
| C | A,B | B-D,U | Any | B |
| C | C,D,U | Any | Any | C |
| D | A,B | B | Any | B |
| D | A,B | C,D,U | Any | C |
| D | C | Any | Any | C |
| D | D,U | Any | Any | D |
| U | A | B,C | Any | B |
| U | B,C | A,B | Any | B |
| U | B,C | C,D,U | Any | C |
| U | U | Any | Any | U |
Four-part score
UBDD
Total Score
C
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| 1.2 |
?Impact on plant community
Consider the cumulative ecological impact of this species to the plant communities it invades. Give more weight to changes in plant composition, structure, and interactions that involve rare or keystone species or rare community types. Examples of severe impacts include:
- formation of stands dominated (>75% cover) by the species;
- occlusion (>75% cover) of a native canopy, including a water surface, that eliminates or degrades layers below;
- significant reduction or extirpation of populations of one or more native species.
Examples of impacts usually less than severe include:
- reduction in propagule dispersal, seedling recruitment, or survivorship of native species;
- creation of a new structural layer, including substantial thatch or litter, without elimination or replacement of a pre-existing layer;
- change in density or depth of a structural layer;
- change in horizontal distribution patterns or fragmentation of a native community;
- creation of a vector or intermediate host of pests or pathogens that infect native plant species.
Select the one letter below that best describes this species' impact on community composition, structure and interactions:
A. Severe alteration of plant community composition, structure, or interactions.
B. Moderate alteration of plant community composition.
C. Minor alteration of community composition.
D. Negligible impact known; causes no perceivable change in community composition, structure, or interactions.
U. Unknown.
|
B. Moderate |
Observational |
| 1.3 |
?Impact on higher trophic levels
Consider the cumulative impact of this species on the animals, fungi, microbes, and other organisms in the communities that it invades. Although a non-native species may provide resources for one or a few native species (e.g. by providing food, nesting sites, etc.), the ranking should be based on the species' net impact on all native species. Give more weight to changes in composition and interactions involving rare or keystone species or rare community types.
Examples of severe impacts include:
- extirpation or endangerment of an existing native species or population;
- elimination or significant reduction in native species' nesting or foraging sites, cover, or other critical resources (i.e., native species habitat), including migratory corridors.
Examples of impacts that are usually less than severe include:
- minor reduction in nesting or foraging sites, cover, etc. for native animals;
- minor reduction in habitat connectivity or migratory corridors;
- interference with native pollinators;
- injurious components, such as awns or spines that damage the mouth and gut of native wildlife species, or production of anti-digestive or acutely toxic chemical that can poison native wildlife species.
Select the one letter below that best describes this species' impact on community composition and interactions:
A. Severe alteration of higher trophic populations, communities, or interactions.
B. Moderate alteration of higher trophic level populations, communities, or interactions.
C. Minor alteration of higher trophic level populations, communities or interactions.
D. Negligible impact; causes no perceivable change in higher trophic level populations, communities, or interactions.
E. Unknown.
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D. Negligible |
Observational |
| 1.4 |
?Impact on genetic integrity
Consider whether the species can hybridize with and influence the proportion of individuals with non-native genes within populations of native species. Mechanisms and possible outcomes include:
- production of fertile or sterile hybrids that can outcompete the native species;
- production of sterile hybrids that lower the reproductive output of the native species.
Select the one letter below that best describes this species' impact on genetic integrity:
A. Severe (high proportion of individuals).
B. Moderate (medium proportion of individuals).
C. Minor (low proportion of individuals).
D. No known hybridization.
U. Unknown.
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D. None |
Reviewed Scientific Publication |
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| 2.1 |
?Role of anthropogenic and natural disturbance in establishment
Assess dependence on disturbance, both human and natural, for establishment of this species in wildlands. Examples of anthropogenic disturbances include:
- grazing, browsing, and rooting by domestic livestock and feral animals;
- altered fire regimes, including fire suppression;
- cultivation;
- silvicultural practices;
- altered hydrology due to dams, diversions, irrigation, etc.;
- roads and trails;
- construction;
- nutrient loading from fertilizers, runoff, etc.
Examples of natural disturbance include:
- wildfire;
- floods;
- landslides;
- windthrow;
- native animal activities such as burrowing, grazing, or browsing.
Select the first letter in the sequence below that describes the ability of this species to invade wildlands:
A. Severe invasive potential: this species can establish independent of any known natural or anthropogenic disturbance.
B. Moderate invasive potential: this species may occasionally establish in undisturbed areas but can readily establish in areas with natural disturbances.
C. Low invasive potential: this species requires anthropogenic disturbance to establish.
D. No perceptible invasive potential: this species does not establish in wildlands (though it may persist from former cultivation).
U. Unknown.
|
A. Severe |
Observational |
Invasiveness?
| Section 2 Scoring Matrix |
| Total points | Score |
| 17-21 | A |
| 11-16 | B |
| 5-10 | C |
| 0-4 | D |
| More than two U's | U |
Total Points
19
Total Score
A
|
| 2.2 |
?Local rate of spread with no management
Assess rate of spread in existing localized infestations where the proportion of available habitat invaded is still small when no management measures are implemented.
Select the one letter below that best describes the rate of spread:
A. Increases rapidly (doubling in <10 years)
B. Increases, but less rapidly
C. Stable
D. Declining
U. Unknown
|
A. Increases rapidly |
Observational |
| 2.3 |
?Recent trend in total area infested within state
Assess the overall trend in the total area infested by this species statewide. Include current management efforts in this assessment and note them.
Select the one letter below that best describes the current trend:
A. Increasing rapidly (doubling in total range statewide in <10 years)
B. Increasing, but less rapidly
C. Stable
D. Declining
U. Unknown
|
A. Increasing rapidly |
Observational |
| 2.4 |
?Innate reproductive potential
(see Worksheet A)
Assess the innate reproductive potential of this species. Worksheet A is provided for computing the score.
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A. High |
Reviewed Scientific Publication |
| 2.5 |
?Potential for human-caused dispersal
Assess whether this species is currently spread: or has high potential to be spread: by direct or indirect human activity. Such activity may enable the species to overcome natural barriers to dispersal that would not be crossed otherwise, or it may simply increase the natural dispersal of the species. Possible mechanisms for dispersal include:
- commercial sales for use in agriculture, ornamental horticulture, or aquariums;
- use as forage, erosion control, or revegetation;
- presence as a contaminant (seeds or propagules) in bulk seed, hay, feed, soil, packing materials, etc.;
- spread along transportation corridors such as highways, railroads, trails, or canals;
- transport on boats or boat trailers.
Select the one letter below that best describes human-caused dispersal and spread:
A. High: there are numerous opportunities for dispersal to new areas.
B. Moderate: human dispersal occurs, but not at a high level.
C. Low: human dispersal is infrequent or inefficient.
D. Does not occur.
U. Unknown.
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A. High |
Observational |
| 2.6 |
? Potential for natural long-distance dispersal
We have chosen 1 km as the threshold of "long-distance." Assess whether this species is frequently spread, or has high potential to be spread, by animals or abiotic mechanisms that can move seed, roots, stems, or other propagules this far. The following are examples of such natural long-distance dispersal mechanisms:
- the species' fruit or seed is commonly consumed by birds or other animals that travel long distances;
- the species' fruits or seeds are sticky or burred and cling to feathers or hair of animals;
- the species has buoyant fruits, seeds, or other propagules that are dispersed by flowing water;
- the species has light propagules that promote long-distance wind dispersal;
- The species, or parts of it, can detach and disperse seeds as they are blown long distances (e.g., tumbleweed).
Select the one letter below that best describes natural long-distance dispersal and spread:
A. Frequent long-distance dispersal by animals or abiotic mechanisms.
B. Occasional long-distance dispersal by animals or abiotic mechanisms.
C. Rare dispersal more than 1 km by animals or abiotic mechanisms.
D. No dispersal of more than 1 km by animals or abiotic mechanisms.
U. Unknown.
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A. Frequent |
Observational |
| 2.7 |
?Other regions invaded
Assess whether this species has invaded ecological types in other states or countries outside its native range that are analogous to ecological types not yet invaded in your state (see Worksheets B, C, and D for California, Arizona, and Nevada, respectively, in Part IV for lists of ecological types). This information is useful in predicting the likelihood of further spread within your state.
Select the one letter below that best describes the species' invasiveness in other states or countries, outside its native range.
A. This species has invaded 3 or more ecological types elsewhere that exist in your state and are as yet not invaded by this species (e.g. it has invaded Mediterranean grasslands, savanna, and maquis in southern Europe, which are analogous to California grasslands, savanna, and chaparral, respectively).
B. Invades 1 or 2 ecological types that exist but are not yet invaded in your state.
C. Invades elsewhere but only in ecological types that it has already invaded in the state.
D. Not known as an escape anywhere else.
U. Unknown.
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C. Already invaded |
Observational |
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| 3.1 |
?Ecological amplitude/Range
(see Worksheet C)
Refer to Worksheet C and select the one letter below that indicates the number of different ecological types that this species invades.
A. Widespread: the species invades at least three major types or at least six minor types.
B. Moderate: the species invades two major types or five minor types.
C. Limited: the species invades only one major type and two to four minor types.
D. Narrow: the species invades only one minor type.
U. Unknown.
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B. Moderate |
Other Published Material |
Distribution?
| Section 3 Scoring Matrix |
| Q 3.1 | Q 3.2 | Score |
| A | A, B | A |
| A | C,D,U | B |
| B | A | A |
| B | B,C | B |
| B | D | C |
| C | A,B | B |
| C | C,D | C |
| D | A | B |
| D | B,C | C |
| D | D | D |
| A,B | U | C |
| C,D | U | D |
| U | U | U |
Total Score
C
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| 3.2 |
?Distribution/Peak frequency
(see Worksheet C)
To assess distribution, record the letter that corresponds to the highest percent infested score entered in Worksheet C for any ecological type.
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D. Very low |
Other Published Material |
Scores are explained in the "Criteria for Categorizing Invasive Non-Native Plants that Threaten Wildlands".
| Section 1: Impact |
Question 1.1 Impact on abiotic ecosystem processes?
Consider the impact on the natural range and variation of abiotic ecosystem processes and system-wide parameters in ways that significantly diminish the ability of native species to survive and reproduce. Alterations that determine the types of communities that can exist in a given area are of greatest concern. Examples of abiotic processes include:
- fire occurrence, frequency, and intensity;
- geomorphological changes such as erosion and sedimentation rates;
- hydrological regimes, including soil water table;
- nutrient and mineral dynamics, including salinity, alkalinity, and pH;
- light availability (e.g. when an aquatic invader covers an entire water body that would otherwise be open).
Select the one letter below that best describes this species' most severe impact on an abiotic ecosystem process:
A. Severe, possibly irreversible, alteration or disruption of an ecosystem process.
B. Moderate alteration of an ecosystem process.
C. Minor alteration of an ecosystem process.
D. Negligible perceived impact on an ecosystem process.
U. Unknown.
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U
Anecdotal
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Identify ecosystem processes impacted:
Deep taproot may draw down the water table, but no studies have been done to document this. Primarily occurs in dry habitats with deeper water table, does occur adjacent to desert washes where moisture is likely to be higher than surrounding areas (McDonald, pers. comm.).
Sources of information:
McDonald, C. Personal communication
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Question 1.2 Impact on plant community composition,
structure, and interactions?
Consider the cumulative ecological impact of this species to the plant communities it invades. Give more weight to changes in plant composition, structure, and interactions that involve rare or keystone species or rare community types. Examples of severe impacts include:
- formation of stands dominated (>75% cover) by the species;
- occlusion (>75% cover) of a native canopy, including a water surface, that eliminates or degrades layers below;
- significant reduction or extirpation of populations of one or more native species.
Examples of impacts usually less than severe include:
- reduction in propagule dispersal, seedling recruitment, or survivorship of native species;
- creation of a new structural layer, including substantial thatch or litter, without elimination or replacement of a pre-existing layer;
- change in density or depth of a structural layer;
- change in horizontal distribution patterns or fragmentation of a native community;
- creation of a vector or intermediate host of pests or pathogens that infect native plant species.
Select the one letter below that best describes this species' impact on community composition, structure and interactions:
A. Severe alteration of plant community composition, structure, or interactions.
B. Moderate alteration of plant community composition.
C. Minor alteration of community composition.
D. Negligible impact known; causes no perceivable change in community composition, structure, or interactions.
U. Unknown.
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B
Observational
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Identify type of impact or alteration:
It is possible that stands of V. tubuliflora could become dense enough to crowd out native vegetation. "My best estimate is that it can outcompete native plants. In Newport there are very few other weeds when the Volutaria canopy is thick (McDonald pers. comm.)." The population in Chula Vista is dense and appears to have been growing for several years (Giessow, pers. comm.).
Based upon field observations, this is a very early germinator (Sept. In Newport Beach), but with only one year of experience as a basis. This very early germination is much sooner that the native flora and likely shades and inhibits the native species. This is similar in phenology to adjacent invasive species in these same areas, such as Brassica nigra, Sisymbrium irio and Bromus spp. There is even observed competition among these species. My other comment has to do with possible allelopathic qualities. Phytotoxins and phenols appear to be documented in several species of the closely related Centaurea genus, although a quick search did not reveal any studies of this with Volutaria. (Vanderhoff, R. pers. comm.).
Sources of information:
Harris et al. 2015
Giessow, J. Personal communication
McDonald, C. Personal communication
Vanderhoff, R. Personal communication
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Question 1.3 Impact on higher trophic levels?
Consider the cumulative impact of this species on the animals, fungi, microbes, and other organisms in the communities that it invades. Although a non-native species may provide resources for one or a few native species (e.g. by providing food, nesting sites, etc.), the ranking should be based on the species' net impact on all native species. Give more weight to changes in composition and interactions involving rare or keystone species or rare community types.
Examples of severe impacts include:
- extirpation or endangerment of an existing native species or population;
- elimination or significant reduction in native species' nesting or foraging sites, cover, or other critical resources (i.e., native species habitat), including migratory corridors.
Examples of impacts that are usually less than severe include:
- minor reduction in nesting or foraging sites, cover, etc. for native animals;
- minor reduction in habitat connectivity or migratory corridors;
- interference with native pollinators;
- injurious components, such as awns or spines that damage the mouth and gut of native wildlife species, or production of anti-digestive or acutely toxic chemical that can poison native wildlife species.
Select the one letter below that best describes this species' impact on community composition and interactions:
A. Severe alteration of higher trophic populations, communities, or interactions.
B. Moderate alteration of higher trophic level populations, communities, or interactions.
C. Minor alteration of higher trophic level populations, communities or interactions.
D. Negligible impact; causes no perceivable change in higher trophic level populations, communities, or interactions.
E. Unknown.
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D
Observational
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Identify type of impact or alteration:
V. tubuliflora becomes tall enough to block movement of animals, if it grows in dense stands. This is occurring in Orange and coastal San Diego County populations. Herbivores seem to prefer native annuals to Volutaria. In the field Volutaria is generally not well grazed by herbivores (most likely caterpillars) and usually only shows minor damage (McDonald, C. pers. comm).
Sources of information:
Harris et al. 2015
Jepson eFlora 2016.
McDonald, C. Personal communication
Vanderhoff, R. Personal communication
Giessow, J. 2016.
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Question 1.4 Impact on genetic integrity?
Consider whether the species can hybridize with and influence the proportion of individuals with non-native genes within populations of native species. Mechanisms and possible outcomes include:
- production of fertile or sterile hybrids that can outcompete the native species;
- production of sterile hybrids that lower the reproductive output of the native species.
Select the one letter below that best describes this species' impact on genetic integrity:
A. Severe (high proportion of individuals).
B. Moderate (medium proportion of individuals).
C. Minor (low proportion of individuals).
D. No known hybridization.
U. Unknown.
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D
Reviewed Scientific Publication
|
Volutaria and its close relative Centaurea are not represented by any native species in California so there is no opportunity to cross with native species and cause impacts to genetic integrity.
Sources of information:
Calflora 2016
Jepson eFlora
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| Section 2: Invasiveness |
Question 2.1 Role of anthropogenic and natural disturbance
in establishment?
Assess this species' dependence on disturbance: both human and natural: for establishment in wildlands. Examples of anthropogenic disturbances include:
- grazing, browsing, and rooting by domestic livestock and feral animals;
- altered fire regimes, including fire suppression;
- cultivation;
- silvicultural practices;
- altered hydrology due to dams, diversions, irrigation, etc.;
- roads and trails;
- construction;
- nutrient loading from fertilizers, runoff, etc.
Examples of natural disturbance include:
- wildfire;
- floods;
- landslides;
- windthrow;
- native animal activities such as burrowing, grazing, or browsing.
Select the first letter in the sequence below that describes the ability of this species to invade wildlands:
A. Severe invasive potential: this species can establish independent of any known natural or anthropogenic disturbance.
B. Moderate invasive potential: this species may occasionally establish in undisturbed areas but can readily establish in areas with natural disturbances.
C. Low invasive potential: this species requires anthropogenic disturbance to establish.
D. No perceptible invasive potential: this species does not establish in wildlands (though it may persist from former cultivation).
U. Unknown.
|
A
Observational
|
Describe role of disturbance:
The pathway for establishment of V. tubuliflora in California is unknown. However, where it has been introduced it spreads rapidly in areas prone to seasonal flooding or along roadsides. It is highly likely that if it is introduced elsewhere it will quickly establish, with or without disturbance. In early 2017 a new large population was found in Upper Newport Bay, located about a mile from the infestation discovered in March 2015. The population contained thousands of plants in some very dense patches, indicating it is not recently established (Vanderhoff, pers. comm.). The two Newport colonies are in rather highly traveled areas and the occurrences tend toward road and trail edges first, but do extend into nondisturbed areas (McDonald, Burger and Vanderhoff, pers. comms.).
In desert it occurs in disturbed and undisturbed areas equally (McDonald, pers. comm). This question is scored as Severe since V. tubuliflora can establish in undisturbed areas.
Sources of information:
Harris et al. 2015
Burger, J. Personal communication.
McDonald, C. Personal communication
Vanderhoff, R. Personal communication
|
Question 2.2 Local rate of spread with no management?
Assess this species' rate of spread in existing localized infestations where the proportion of available habitat invaded is still small when no management measures are implemented.
Select the one letter below that best describes the rate of spread:
A. Increases rapidly (doubling in <10 years)
B. Increases, but less rapidly
C. Stable
D. Declining
U. Unknown
|
A
Observational
|
Describe rate of spread:
V. tubuliflora was first thought to be introduced in Borrego Springs in 2010, with a small number of plants observed in 2011, 2012 and 2013. After the monsoonal flooding in summer 2013, almost one thousand plants germinated in the mud left behind by the water. After Borrego Springs finally got some decent winter rain in late 2014, almost ten thousand plants germinated, a factor of ten more plants than were seen one year earlier. In early 2017 a new large population was found in Upper Newport Bay, located about a mile from the infestation discovered in March 2015. The population contained thousands of plants in some very dense patches, indicating it is not recently established (Vanderhoff, pers. comm.). Recently an herbarium specimen from 1987 from the population in Newport Bay was determined to be V. tubuliflora, moving the introduction date back to that time. This indicates the rate of spread of the Newport Bay population is perhaps B, increasing less rapidly (Vanderhoff, pers. comm.), however Burger considers the rate of spread as an A for the Newport Bay population. This question is scored as A since the Borrego Springs population is thought to be increasing at that rate.
Sources of information:
Harris et al. 2015
McDonald, C. Personal communication
Vanderhoff, R. Personal communication
|
Question 2.3 Recent trend in total area infested within state?
Assess the overall trend in the total area infested by this species statewide. Include current management efforts in this assessment and note them.
Select the one letter below that best describes the current trend:
A. Increasing rapidly (doubling in total range statewide in <10 years)
B. Increasing, but less rapidly
C. Stable
D. Declining
U. Unknown
|
A
Observational
|
Describe trend:
V. tubuliflora was first discovered in Borrego Springs in 2010, with a small number of plants observed in 2011, 2012 and 2013. After the monsoonal flooding in summer 2013, almost one thousand plants germinated in the mud left behind by the water. After Borrego Springs finally got some decent winter rain in late 2014, almost ten thousand plants germinated, a factor of ten more plants than were seen one year earlier. V. tubuliflora was detected in Orange County in 2015 with as many as 3,000 plants, and recently R. vanderhoff located another population with thousands of plants a mile from the previous detection (Vanderhoff pers comm.). In 2016, Jason Giessow reported a 1.2 acre population with over 50,000 plants in Chula Vista, coastal San Diego county. This population is likely a few years old given its density and extent (Giessow 2016).
Sources of information:
Harris et al. 2015
Giessow, J. Personal communication
Giessow, J. 2016
Vanderhoff, R. Personal communication
|
Question 2.4 Innate reproductive potential?
Assess the innate reproductive potential of this species. Worksheet A is provided for computing the score.
|
A
Reviewed Scientific Publication
|
Describe key reproductive characteristics:
Annual plant which blooms from April to June in California (Jepson eFlora). Bloom can be as early as January in the desert in irrigated orchards and March along roadsides (McDonald, pers. comm.). Additionally, blooming was observed starting in February 2016 in Orange County, and as late as April when they were pulled so the end of flowering in that population was not observed that year (Vanderhoff pers. comm.)
Sources of information:
Jepson eFlora 2016
McDonald, C. Personal communication
Vanderhoff, R. Personal communication
|
Question 2.5 Potential for human-caused dispersal?
Assess whether this species is currently spread: or has high potential to be spread: by direct or indirect human activity. Such activity may enable the species to overcome natural barriers to dispersal that would not be crossed otherwise, or it may simply increase the natural dispersal of the species. Possible mechanisms for dispersal include:
- commercial sales for use in agriculture, ornamental horticulture, or aquariums;
- use as forage, erosion control, or revegetation;
- presence as a contaminant (seeds or propagules) in bulk seed, hay, feed, soil, packing materials, etc.;
- spread along transportation corridors such as highways, railroads, trails, or canals;
- transport on boats or boat trailers.
Select the one letter below that best describes human-caused dispersal and spread:
A. High: there are numerous opportunities for dispersal to new areas.
B. Moderate: human dispersal occurs, but not at a high level.
C. Low: human dispersal is infrequent or inefficient.
D. Does not occur.
U. Unknown.
|
A
Observational
|
Identify dispersal mechanisms:
It is not known how V. tubuliflora was introduced into California, but human introduction is the likely vector. Since its introduction it has been found along roadsides, in disturbed areas and at trail heads. Its also found in 3 well separated populations each about 80 miles apart. So long distance, and most likely human, dispersal seems quite probable (McDonald, C. pers. comm.).
Sources of information:
Calflora 2016
Harris et al. 2015
McDonald, C. Personal communication
|
Question 2.6 Potential for natural long-distance dispersal?
We have chosen 1 km as the threshold of "long-distance." Assess whether this species is frequently spread, or has high potential to be spread, by animals or abiotic mechanisms that can move seed, roots, stems, or other propagules this far. The following are examples of such natural long-distance dispersal mechanisms:
- the species' fruit or seed is commonly consumed by birds or other animals that travel long distances;
- the species' fruits or seeds are sticky or burred and cling to feathers or hair of animals;
- the species has buoyant fruits, seeds, or other propagules that are dispersed by flowing water;
- the species has light propagules that promote long-distance wind dispersal;
- The species, or parts of it, can detach and disperse seeds as they are blown long distances (e.g., tumbleweed).
Select the one letter below that best describes natural long-distance dispersal and spread:
A. Frequent long-distance dispersal by animals or abiotic mechanisms.
B. Occasional long-distance dispersal by animals or abiotic mechanisms.
C. Rare dispersal more than 1 km by animals or abiotic mechanisms.
D. No dispersal of more than 1 km by animals or abiotic mechanisms.
U. Unknown.
|
A
Observational
|
Identify dispersal mechanisms:
V. tubuliflora was observed to be spreading after flooding-induced rains in Borrego Springs. It could also be spread by wind.
Dispersal distances can be over 1 km (McDonald, pers. comm.).
Sources of information:
Calflora 2016
Harris et al. 2015
McDonald, C. Personal communication
|
Question 2.7 Other regions invaded?
Assess whether this species has invaded ecological types in other states or countries outside its native range that are analogous to ecological types not yet invaded in your state (see Worksheets B, C, and D for California, Arizona, and Nevada, respectively, in Part IV for lists of ecological types). This information is useful in predicting the likelihood of further spread within your state.
Select the one letter below that best describes the species' invasiveness in other states or countries, outside its native range.
A. This species has invaded 3 or more ecological types elsewhere that exist in your state and are as yet not invaded by this species (e.g. it has invaded Mediterranean grasslands, savanna, and maquis in southern Europe, which are analogous to California grasslands, savanna, and chaparral, respectively).
B. Invades 1 or 2 ecological types that exist but are not yet invaded in your state.
C. Invades elsewhere but only in ecological types that it has already invaded in the state.
D. Not known as an escape anywhere else.
U. Unknown.
|
C
Observational
|
Identify other regions:
V. tubuliflora is native to the Canary Islands, northern Africa and southern Europe. It is also invasive in Saudi Arabia and Chile. In Chile it grows in arid desert in an area with 20 to 30mm annual precipitation (Tellier 2014). While it has invaded desert habitats in San Diego County, its presence in Newport Bay and coastal San Diego County indicate it has the potential to spread into more community types which are not yet invaded.
Sources of information:
Calflora 2016
Harris et al. 2015
McDonald 2016
McDonald, C. Personal communication
Teillier et al. 2014
|
| Section 3: Distribution |
Question 3.1 Ecological amplitude/Range?
Refer to Worksheet C and select the one letter below that indicates the number of different ecological types that this species invades.
A. Widespread: the species invades at least three major types or at least six minor types.
B. Moderate: the species invades two major types or five minor types.
C. Limited: the species invades only one major type and two to four minor types.
D. Narrow: the species invades only one minor type.
U. Unknown.
|
B
Other Published Material
|
V. tubuliflora (then called V. canariensis) was first documented in California in February 2010 and was vouchered in 2011 in San Diego County near Borrego Springs. Since that time it has been detected in Orange County and in coastal San Diego county. When V. tubuliflora was first detected in San Diego it was mis-identified as V. canariensis, and is still listed in the Jepson eFlora as V. canariensis Recent review of an herbarium specimen of V. muricata from Newport Bay area indicates that the species was actually V. tubuliflora, which would move the introduction date of the species in California to 1987 in Orange County (McDonald pers. comm.)
Sources of information:
Calflora 2016
CCH 2016
Harris et al. 2015
Jepson eFlora 2016
McDonald, C. Personal communication
|
Question 3.2 Distribution/Peak frequency?
To assess distribution, record the letter that corresponds to the highest percent infested score entered in Worksheet C for any ecological type.
|
D
Other Published Material
|
Describe distribution:
V. tubuliflora occurs in desert dunes and scrub, as well as coastal scrub and urban road edges in Southern California. Currently populations are small where it occurs (Calflora).
Sources of information:
CCH 2016
Calflora 2016
Harris et al. 2015
Jepson eFlora 2016
Giessow 2016
|
| Reaches reproductive maturity in 2 years or less |
Yes |
| Dense infestations produce >1,000 viable seed per square meter |
Yes |
| Populations of this species produce seeds every year. |
Yes |
| Seed production sustained over 3 or more months within a population annually |
Yes |
| Seeds remain viable in soil for three or more years |
Yes |
| Viable seed produced with both self-pollination and cross-pollination |
Unknown |
| Has quickly spreading vegetative structures (rhizomes, roots, etc.) that may root at nodes |
No |
| Fragments easily and fragments can become established elsewhere |
No |
| Resprouts readily when cut, grazed, or burned |
No |
| Total points: |
7
|
| Total unknowns: |
1 |
| Total score: |
A?
Scoring Criteria for Worksheet A
A. High reproductive potential (6 or more points).
B. Moderate reproductive potential (4-5 points).
C. Low reproductive potential (3 points or less and less than 3 Unknowns).
U. Unknown (3 or fewer points and 3 or more Unknowns).
|
Related traits:
Each plant produces 2,500 seeds (OC CNPS). Blooming period may be as long as February to June, so seed production is assumed to be over three months (Vanderhoff pers. comm.) Plants found in 2014 in Big Canyon, Orange County, are still germinating in 2017, so seeds are viable for more than 3 years (J. Burger, pers. comm.)
Worksheet B - Arizona Ecological Types is not included here
(sensu Holland 1986)
| Major Ecological Types |
Minor Ecological Types |
Code?
A means >50% of type occurrences are invaded;
B means 20% to 50%;
C means 5% to 20%;
D means present but <5%;
U means unknown (unable to estimate percentage of occurrences invaded)
|
| Marine Systems | marine systems | |
| Freshwater and Estuarine | lakes, ponds, reservoirs | |
| Aquatic Systems | rivers, streams, canals | |
| estuaries | |
| Dunes | coastal | |
| desert | D, < 5% |
| interior | |
| Scrub and Chaparral | coastal bluff scrub | |
| coastal scrub | D, < 5% |
| Sonoran desert scrub | D, < 5% |
| Mojavean desert scrub (incl. Joshua tree woodland) | |
| Great Basin scrub | |
| chenopod scrub | |
| montane dwarf scrub | |
| Upper Sonoran subshrub scrub | |
| chaparral | |
| Grasslands, Vernal Pools, Meadows, and other Herb Communities | coastal prairie | |
| valley and foothill grassland | |
| Great Basin grassland | |
| vernal pool | |
| meadow and seep | |
| alkali playa | |
| pebble plain | |
| Bog and Marsh | bog and fen | |
| marsh and swamp | |
| Riparian and Bottomland habitat | riparian forest | |
| riparian woodland | |
| riparian scrub (incl.desert washes) | |
| Woodland | cismontane woodland | |
| piñon and juniper woodland | |
| Sonoran thorn woodland | |
| Forest | broadleaved upland forest | |
| North Coast coniferous forest | |
| closed cone coniferous forest | |
| lower montane coniferous forest | |
| upper montane coniferous forest | |
| subalpine coniferous forest | |
| Alpine Habitats | alpine boulder and rock field | |
| alpine dwarf scrub | |
|
Amplitude (breadth): |
B |
|
Distribution (highest score): |
D |
Infested Jepson Regions
Click here for a map of Jepson regions
